WO2020222402A1 - Dispositif de génération d'image - Google Patents

Dispositif de génération d'image Download PDF

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Publication number
WO2020222402A1
WO2020222402A1 PCT/KR2020/001141 KR2020001141W WO2020222402A1 WO 2020222402 A1 WO2020222402 A1 WO 2020222402A1 KR 2020001141 W KR2020001141 W KR 2020001141W WO 2020222402 A1 WO2020222402 A1 WO 2020222402A1
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WO
WIPO (PCT)
Prior art keywords
optical fiber
signal
phase
light
image
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Ceased
Application number
PCT/KR2020/001141
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English (en)
Korean (ko)
Inventor
황경민
이정호
이건희
정기훈
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
VPIX Medical Inc
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VPIX Medical Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from KR1020190112711A external-priority patent/KR102301809B1/ko
Application filed by VPIX Medical Inc filed Critical VPIX Medical Inc
Priority to CN202080033166.7A priority Critical patent/CN113766866B/zh
Priority to AU2020266362A priority patent/AU2020266362B2/en
Priority to EP24215231.2A priority patent/EP4488935A3/fr
Priority to CA3132593A priority patent/CA3132593A1/fr
Priority to CN202411605868.4A priority patent/CN119279471A/zh
Priority to EP20798082.2A priority patent/EP3936028A4/fr
Publication of WO2020222402A1 publication Critical patent/WO2020222402A1/fr
Anticipated expiration legal-status Critical
Priority to AU2023200313A priority patent/AU2023200313B2/en
Ceased legal-status Critical Current

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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/04Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor combined with photographic or television appliances
    • A61B1/05Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor combined with photographic or television appliances characterised by the image sensor, e.g. camera, being in the distal end portion
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B1/00Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor
    • A61B1/06Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor with illuminating arrangements
    • A61B1/07Instruments for performing medical examinations of the interior of cavities or tubes of the body by visual or photographical inspection, e.g. endoscopes; Illuminating arrangements therefor with illuminating arrangements using light-conductive means, e.g. optical fibres
    • GPHYSICS
    • G06COMPUTING OR CALCULATING; COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T7/00Image analysis

Definitions

  • the following embodiments relate to an image generating device for observing the inside of an object in real time and an image generating method using the image generating device.
  • Optical devices are for observing the inside and outside of an object by irradiating light, and are widely used in various medical fields, biology research, and industrial fields.
  • a microscopic microscope for observing the characteristics of a living body in real time is being developed, and in order to observe a pathological state in real time through minimal incision, it is necessary to miniaturize the device and to provide a high-resolution image.
  • the following embodiments aim to provide an image having a high resolution by irradiating a preset scanning pattern on an object.
  • the following embodiments aim to provide an image having a high resolution by changing the phase of the scanning pattern in real time.
  • the following embodiments aim to match an input signal for driving an optical fiber into a scanning pattern and an output signal for actually driving an optical fiber by attaching a structure.
  • the following embodiments aim to prevent damage to the structure by separating the distance of the structure from the end when the optical fiber is driven.
  • the following embodiments aim to control the aspect ratio of the output image by adjusting the voltage level of the optical fiber input signal.
  • the following embodiments aim to primarily correct the phase of the image when the probe is mounted on the cradle using the cradle.
  • the following embodiments aim to correct the phase of an output image by using a difference value between light intensity values obtained at one pixel location.
  • the following embodiments aim to provide a method of searching for a phase for correcting an output image using a predetermined phase change period.
  • an optical fiber having a fixed end and a free end;
  • a first actuating unit configured to apply a first force on an actuator position between the fixed end and the free end of the optical fiber to guide the free end of the optical fiber to drive in a first direction;
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is disposed at a first rod position on the optical fiber, , The second end is disposed at a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the The first rod position of the optical fiber from the first end of the deformable rod, on a cross-section perpendicular to the longitudinal direction of the optical fiber and arranged parallel to the optical fiber from the first rod position to the second rod position
  • the angle between the virtual line connected to and the first direction is arranged to be within a preset range, so that the free end of the
  • an image generating apparatus comprising an irradiation unit for irradiating light to an object, a light receiving unit for receiving a signal returned from the object, and a control unit for generating an image based on a signal obtained from the light receiving unit, the fixed end and An optical fiber having a free end; It is located at an actuator position between the fixed end and the free end of the optical fiber, and is configured to apply a first force on the actuator position to induce the free end of the optical fiber to resonantly drive in a first direction.
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is fixed at a position of the first rod on the optical fiber , The second end is fixed to a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the Arranged in parallel with the optical fiber from the first rod position to the second rod position, the deformable rod has a free end of the optical fiber in the first direction according to the first force applied from the first actuating part.
  • An image generating apparatus may be provided in which an angle between a virtual line connected to the first rod position of the optical fiber from the first end of the rod and the first direction is within a preset range.
  • an optical fiber having a fixed end and a free end; A first positioned at an actuator position between the fixed end and the free end of the optical fiber and configured to apply a first force on the actuator position to induce the free end of the optical fiber to drive in a first direction Actuating unit; A second actuating unit configured to apply a second force to the actuator position of the optical fiber to guide the free end of the optical fiber to drive in a second direction perpendicular to the first direction; A control unit for applying a first driving signal to the first actuating unit and a second driving signal to the second actuating unit; And a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is disposed at a first rod position on the optical fiber, , The second end is disposed at a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the The first rod
  • an optical fiber having a fixed end and a free end; A first positioned at an actuator position between the fixed end and the free end of the optical fiber and configured to apply a first force on the actuator position to induce the free end of the optical fiber to drive in a first direction Actuating unit; A second actuating unit configured to apply a second force to the actuator position of the optical fiber to guide the free end of the optical fiber to drive in a second direction perpendicular to the first direction; A housing for accommodating the optical fiber and the first and second actuating parts; a mass body having a predetermined size is attached between the fixed end and the free end of the optical fiber, and the mass body includes the optical fiber having the first force and When the second force vibrates, the mass body is attached within a collision avoidance distance range adjacent to the free end side of the optical fiber to prevent damage by colliding with the inner wall of the housing, and the collision prevention distance range includes the optical fiber.
  • An optical device in which at least one of the maximum driving range of the optical fiber from the center of the housing inner diameter and the
  • an apparatus for irradiating light to an object comprising: a control module that generates driving signals; and an irradiator configured to receive the driving signals from the control module and irradiate light to the object based on the driving signals ; And a first driving signal having a first driving frequency and a first phase among the driving signals, and a second driving signal having a second driving frequency and a second phase.
  • a third driving signal having a first driving frequency and a third phase and a fourth driving signal having a second driving frequency and a fourth phase are applied to the irradiation unit.
  • control module includes a phase difference between the first phase and the second phase and a phase difference between the third phase and the fourth phase n times a predetermined phase.
  • An optical device may be provided that generates the first to fourth drive signals to make a difference.
  • a control module for generating driving signals the control module for irradiating light to an object, obtaining light returning from the object, and obtaining an image of the object using the obtained light
  • the method of generating a pattern in an optical device including an irradiator for receiving the driving signals from and irradiating light to the object based on the driving signals comprising: a first driving frequency and a first phase among the driving signals When a first driving signal and a second driving signal having a second driving frequency and a second phase are applied to the irradiating unit, irradiating light from the irradiating unit according to a first scanning pattern; When a third driving signal having a first driving frequency and a third phase among the driving signals and a fourth driving signal having a second driving frequency and a fourth phase is applied to the irradiating unit, the irradiating unit is applied to the second scanning pattern.
  • the control control module generates the first to fourth driving signals such that a phase difference between the first phase and the second phase and a phase difference between the third phase and the fourth phase are n times a predetermined phase difference.
  • a light irradiation method comprising; may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information To obtain a plurality of data sets, and determine a data set for obtaining an image of good quality according to a predetermined criterion among the plurality of data sets, the plurality of data sets being the first of the first signal A phase-adjusted data set obtained when at least one of a phase component or the second phase component of the second signal is adjusted, and the image of the object uses the determined data set among the plurality of data sets
  • an image generating device that is generated may be provided.
  • a control module in an image generation method of obtaining an image of an object by irradiating light, a control module generates a first signal having a first frequency component and a first phase component in a first axis direction, and a second axis Generating a second signal having a second frequency component and a second phase component in a direction; Irradiating light to the object by using the first signal and the second signal by a scanning unit; And acquiring light-receiving information from the light returned from the object according to the light irradiated by the scanning unit in the light receiving unit, wherein the control module includes: the first signal, the second signal, and the A plurality of data sets are obtained using light-receiving information, and a data set for obtaining a good quality image according to a predetermined criterion is determined among the plurality of data sets, and the plurality of data sets A phase-adjusted data set obtained when at least one of a first phase component or the second phase component of the second signal is adjusted, and
  • the image generating apparatus in an image generating apparatus to irradiate light to an object by using a Lisaju pattern and acquire an image of the object based on the returned light, includes a control module, a driving unit, and a scanning unit. And a light receiving unit, wherein the control module includes a first driving signal, a second frequency component, and a second phase component including a first frequency component and a first phase component in order to irradiate light to the object according to a Lissajous pattern.
  • a driving signal including a second driving signal including a second driving signal is applied to a driving unit, and the driving unit receives the driving signal from the control module, and the scanning unit receives a first scanning unit output signal and a second output signal corresponding to the first driving signal.
  • the light receiving unit acquires the intensity of light returned from the object based on the light irradiated by the scanning unit
  • the control module includes the first driving signal and the second driving signal and the In order to correct that the phase components of the output signal of the first scanning unit and the output signal of the second scanning unit are different from each other, a difference in the phase component between the first driving signal and the output signal of the first scanning unit occurs, and the second driving
  • the control module uses the first driving signal, the second driving signal, and the intensity of the light obtained through the light receiving unit to set the first data.
  • a data set having a small difference in phase component between output signals of the ning unit may be determined, and the determined data set may be provided with an image generating apparatus used to generate an image of an object.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a first signal is generated in a second axis direction.
  • a control module for generating a second signal having a second frequency component and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module comprises: a position of a first signal-corresponding pixel-the first signal-corresponding pixel The position is obtained based on the first signal and the second signal-A first data set is obtained based on the signal and the light-receiving information, and at least one of signals corresponding to the pixel position corresponding to the first signal A phase component is changed by a first phase change period, and a second data set is obtained based on a second signal-corresponding pixel position based on a change in the phase component, and the second data set is a predetermined value compared to the first data set.
  • At least one phase component of the phase components of the signals corresponding to the position of the second signal corresponding pixel is changed by the first phase change period, and the third signal-corresponding pixel based on the change in the phase component
  • a third data set is obtained based on a position and the second data set more meets a predetermined criterion than the third data set
  • a reconstructed pixel position image for the object is generated based on the second data set.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information A first data set is obtained by using, and the phase component of at least one signal among the first signal or the second signal is changed a plurality of times by a first phase change period, and each signal and light received by the plurality of times are changed.
  • n is an integer greater than or equal to 2-At least one signal in which the phase component is changed n times by the first phase change period and the light reception
  • the n-th data set is obtained by using information, and the n-1-th data set is obtained before the n-th data set-The n-th data set is at least one of the first signal or the second signal.
  • the phase component of the signal is changed n-1 times by the first phase change period-If the n-th data set meets a predetermined criterion, at least one of the first signal or the second signal N+1th data using at least one signal in which the phase component of is changed n+1 times by the first phase change period and the phase component is changed n+1 times by the first phase change period and the light reception information
  • the phase component is based on at least one signal changed n-1 times by the first phase change period
  • An image generating device for generating a raw image may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component;
  • a scanning unit irradiating light to the object using the first signal and the second signal;
  • a light-receiving unit for acquiring light-receiving information based on light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes a predetermined value in the first phase component of the first signal.
  • an image generating apparatus may be provided that generates an image by using the first data set obtained based on the first phase change signal.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information A first data set is obtained based on, and a second data set obtained by changing signals corresponding to the first data set by a preset phase change period is obtained, and the second data set is predetermined compared to the first data set.
  • a third data set obtained by changing signals corresponding to the second data set by the preset phase change period is obtained, and the second data set is a predetermined criterion than the third data set. If it is more consistent with, an image generating apparatus for generating an image of the object based on the second data set may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a first signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component;
  • a scanning unit irradiating light to the object using the first signal and the second signal;
  • a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module comprises: the first signal and the second signal at a first time point.
  • a first image is generated and output using, and the phase of at least one of the first signal and the second signal is changed during a predetermined time period after the first time point, and after the predetermined time period Generates and outputs a second image using at least one signal whose phase has been changed at a second time point, wherein the phase of the first signal at the first time point and the phase of the first signal at the second time point
  • the difference and the difference between the phase of the second signal at the first time point and the phase of the second signal at the second time point is substantially an integer multiple difference based on a predetermined phase change period, and the predetermined phase change
  • An image generating apparatus may be provided in which a period is determined based on the first frequency component and the second frequency component.
  • generating a first signal having a first frequency component and a first phase component in a first axis direction, and generating a second signal having a second frequency component and a second phase component in a second axis direction A control module, a scanning unit that irradiates light to the object using the first signal and the second signal, and acquires light reception information by light returned from the object according to the light irradiated by the scanning unit
  • An image generating method of an image generating apparatus including a light receiving unit and irradiating light to obtain an image of an object, wherein the control module includes a first signal-corresponding pixel position-the first signal-corresponding pixel position is the first signal and the Obtained based on a second signal-obtaining a first data set based on a signal and the light received information; At least one phase component of the signals corresponding to the position of the pixel corresponding to the first signal is changed by a first phase change period, and a second data set is obtained based on the position of the pixel corresponding to the first signal
  • At least one phase component of the phase components of signals corresponding to the pixel position corresponding to the second signal is the first phase change period A step that is changed by; And obtaining a third data set based on a third signal-corresponding pixel position based on a change in the phase component, and if the second data set more meets a predetermined criterion than the third data set, the second data set.
  • An image generation method including; generating an image of the object based on may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second frequency component and a second signal are generated in a second axis direction.
  • a control module for generating a second signal having a phase component; and a scanning unit for irradiating light to the object using the first signal and the second signal, wherein the control module includes a pixel corresponding to a first signal
  • a first data set is obtained based on a location-the location of the pixel corresponding to the first signal is obtained based on the first signal and the second signal, and at least one of the signals corresponding to the location of the pixel corresponding to the first signal
  • One phase component is changed by a first phase change period, and a second data set is obtained based on a second signal-corresponding pixel position based on a change in the phase component, and the second data set is greater than the first data set.
  • At least one phase component of the phase components of the signals corresponding to the position of the pixel corresponding to the second signal is changed by the first phase change period, and a third signal based on the change of the phase component If a third data set is obtained based on a corresponding pixel position, and the second data set more meets a predetermined criterion than the third data set, the position of light irradiated to the object based on the second data set and A light irradiation device may be provided to determine the location of the pixel so that the location of the pixel corresponding to the second signal corresponds.
  • a mounting device for mounting an image generating device comprising a probe, irradiating light to an object at one end of the probe, and receiving light returned from the object at the one end, the image A housing containing at least a portion of the generating device, the at least part comprising the one end;
  • phase correction of a driving signal for determining a position at which light is irradiated to the object from the one end is performed, at least one A reference image providing unit providing a reference image; wherein the reference image providing unit is an image in which a position of the reference image is adjusted such that a distance between one end of the probe and the reference image is adjusted to a focal length of the probe
  • a mounting device for mounting the generating device may be provided.
  • a mounting device for mounting an image generating device comprising a probe, irradiating light to an object at one end of the probe, and receiving light returned from the object at the one end, the image A housing containing at least a portion of the generating device, the at least part comprising the one end;
  • a plurality of references may be performed to perform phase correction of a driving signal that determines a position at which light is irradiated to the object from the one end.
  • a reference image providing unit for providing an image wherein the reference image providing unit comprises: a plurality of reference images in which each of the plurality of reference images is arranged such that a distance between one end of the probe and the reference image is adjusted to a focal length of the probe.
  • a mounting device for mounting an image generating device including a layer of may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a first signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for obtaining light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes an input signal input to the scanning unit and the scanning unit operating In order to correct the phase difference between the actual signals, phase correction is performed on the input signal, but the scanning unit is mounted on the mounting device-the mounting device has a reference image disposed therein-and the mounting from the scanning unit When light is irradiated toward the reference image disposed inside the device, first-order phase correction is performed on the input signal using light-receiving information based on light returned from the reference image, and the scanning unit When light is irradiated from the scanning unit toward the object without being mounted, a second-order phase correction is repeatedly performed on the input signal at predetermined periods using a light-receiving signal based on
  • generating a first signal having a first frequency component and a first phase component in a first axis direction, and generating a second signal having a second frequency component and a second phase component in a second axis direction A control module, a scanning unit that irradiates light to the object using the first signal and the second signal, and acquires light reception information by light returned from the object according to the light irradiated by the scanning unit
  • a phase correction method of an image scanning apparatus including a light receiving unit and irradiating light to obtain an image of an object, wherein the phase difference between an input signal input to the scanning unit and an actual signal operated by the scanning unit is corrected, the Performing, by a control module, phase correction on the input signal; Including, the step of performing the phase correction, in a state where the scanning unit is mounted on the mounting device-the mounting device has a reference image disposed therein-the reference image disposed inside the mounting device from the scanning unit Performing a first-order phase correction on the input signal by using light-rece
  • a compact optical device capable of observing inside and outside an object in real time may be provided.
  • an image having a high resolution may be provided by correcting a phase delay generated from a difference between a driving signal and an output signal.
  • a structure for separating a frequency to each axis of an optical fiber, an attachment position of the structure, and an attachment angle of the structure may be provided.
  • a probe cradle for primarily correcting the phase of an output image may be provided.
  • an output image in which an aspect ratio is adjusted by adjusting a voltage of a signal input to an optical fiber may be provided.
  • a high resolution image may be provided by adjusting the phase of a signal input to the optical fiber.
  • a method of finding a phase for correcting an output image using a predetermined phase change period may be provided.
  • a method of correcting the phase of an output image may be provided by using a difference value between light intensity values obtained at one pixel location.
  • FIG. 1 is a diagram illustrating an environment in which an image generating device according to an exemplary embodiment of the present application is used.
  • FIG. 2 is a block diagram illustrating an exemplary configuration of an image generating apparatus according to an exemplary embodiment of the present application.
  • FIG. 3 is a diagram illustrating a configuration of a scanning module according to an exemplary embodiment of the present application.
  • FIG. 4 is a diagram illustrating various scanning patterns according to an exemplary embodiment of the present application.
  • FIG. 5 is a block diagram illustrating a configuration of an image processing module 200 according to an exemplary embodiment of the present application.
  • FIG. 6 is a block diagram illustrating an internal configuration of the scanning module 110 according to an exemplary embodiment of the present application.
  • FIG. 7 is a cross-sectional view illustrating an internal configuration of the scanning module 110 according to an embodiment of the present application.
  • FIG. 8 is a diagram illustrating a beam output when an optical fiber according to another embodiment of the present application is processed into a conical or hemispherical shape.
  • FIGS. 9 and 10 are views exemplarily illustrating a configuration of a lens module according to an embodiment of the present application.
  • FIG. 11 is a diagram illustrating a structure of a scanning unit according to an exemplary embodiment of the present application.
  • FIG. 12 is a graph exemplarily illustrating design conditions of a scanning unit according to an embodiment of the present application.
  • FIG. 13 and 14 are views exemplarily illustrating an attachment position of a mass body M according to an embodiment of the present application.
  • 15 is a graph for explaining frequency separation according to an embodiment of the present application.
  • 16 to 18 are views exemplarily illustrating a structure of a driving range adjusting means according to an exemplary embodiment of the present application.
  • FIG. 19 is a diagram exemplarily illustrating an eccentricity phenomenon according to an embodiment of the present application.
  • 20 is a view for explaining the principle of vibration of an optical fiber according to another embodiment of the present application.
  • 21 and 22 are views for explaining an attachment position of a deformable rod according to embodiments of the present application.
  • FIG. 24 is a diagram for illustratively explaining Lisaju scanning according to an embodiment of the present application.
  • 25 is a diagram for illustratively explaining an attachment angle range of a deformable rod according to an embodiment of the present application.
  • 26 is a diagram exemplarily illustrating a coupling error according to an embodiment of the present application.
  • 27 is a graph exemplarily illustrating an attachment angle range of a damping wire according to an embodiment of the present application.
  • 28 to 30 are views showing frequency characteristics according to the attachment direction of the damping wire described above.
  • FIG. 31 is a flowchart illustrating an aspect ratio correction method according to an exemplary embodiment of the present application.
  • FIGS. 32 to 34 are views for explaining a coupling structure for accommodating each component in a housing in the scanning module 110 according to the exemplary embodiments of the present application.
  • 35 is a diagram illustrating an internal structure of a scanning module according to another embodiment of the present application.
  • 36 is a diagram illustrating an internal structure of a scanning module according to still another embodiment of the present application.
  • FIG. 37 is a diagram illustrating a computer system in which embodiments described in the present specification may be implemented.
  • 38 is a diagram showing a waveform of a signal before a phase is delayed and a waveform of a signal after a phase is delayed.
  • FIG. 39(a) is a diagram showing a low-resolution image in which the phase is delayed
  • FIG. 39(b) is a diagram showing a high-resolution image whose phase is corrected.
  • 40 is a diagram showing fine patterning appearing on a pattern of light irradiated with light.
  • 41 is a diagram showing the contrast according to a cut-off filter appearing on a pattern of light irradiated with light.
  • FIG. 42(a) is a diagram showing that an unused area occurs in an acquired image when the phase is delayed
  • FIG. 42(b) is a view showing that an unused area occurs at a corner in the acquired image when the phase is corrected. .
  • 43 is a block diagram showing a mounting device according to an embodiment.
  • 44 is a diagram illustrating that a scanning module is accommodated in an image generating apparatus according to an embodiment.
  • 45 is a diagram for explaining that a scanning module is mounted on a mounting device according to an embodiment.
  • 46 is a cross-sectional view illustrating a receiving portion of the mounting device according to an embodiment from an upper portion of the receiving portion.
  • 47 is a top view showing a reference pattern unit according to an embodiment.
  • FIG. 48 is a side view illustrating a reference image present on a reference pattern portion according to an exemplary embodiment.
  • 49 is a side view illustrating a reference pattern part existing in a concave structure according to an exemplary embodiment.
  • FIG. 50A is a view showing that the reference pattern part at the bottom of the mounting device according to an embodiment moves to the top through the adjusting part
  • FIG. 50B is a reference pattern part at the bottom of the mounting device according to an embodiment It is a diagram showing the movement to the bottom through.
  • 51 is a flowchart illustrating phase correction using a reference image existing in a mounting apparatus according to an exemplary embodiment.
  • FIG. 52 is a table showing a method of storing signals acquired by a control module according to an embodiment.
  • FIG. 53A is a table showing a method of storing acquired signals when there is no phase delay according to an embodiment
  • FIG. 53B is a case where there is a phase delay according to an embodiment
  • 54 is a diagram for describing obtaining a difference between signal values acquired at a prediction time point on a pattern of light, according to an exemplary embodiment.
  • 55 is a flowchart for describing phase correction using a difference between values obtained at a prediction time point on a light pattern according to an exemplary embodiment.
  • FIG. 56 is a flowchart for describing phase correction using values acquired for pixels of an image acquired by a control module according to an exemplary embodiment.
  • 57 is a diagram illustrating standard deviation information according to a change in a phase according to an embodiment.
  • 58 is a diagram for describing a method of finding a value at which standard deviation information is minimum, according to an exemplary embodiment, according to a trajectory.
  • 59 is a diagram for explaining a method of finding a value at which standard deviation information is minimum, by limiting a range, according to an exemplary embodiment.
  • 60 is a diagram for explaining that a local minimum value appears when a minimum value of standard deviation information is found using a trajectory according to an exemplary embodiment.
  • 61 is a diagram for describing a change in FF according to a phase change according to an embodiment.
  • 62 is a flowchart illustrating searching according to a trajectory in order to search for a phase having the smallest standard deviation information according to an embodiment.
  • 63 is a diagram for describing a method of finding a phase at which standard deviation information is minimum, according to an embodiment, according to a trajectory.
  • 64 is a diagram for describing a method of finding a phase at which standard deviation information is minimum, according to an embodiment, according to a trajectory.
  • 65 is a flowchart illustrating a method of searching for a phase having the smallest standard deviation information by limiting a range after searching according to a trajectory according to an exemplary embodiment.
  • 66 is a flowchart illustrating a method of searching for a phase having the smallest standard deviation information by reducing a phase search unit after searching for a phase according to a trajectory in correcting a phase according to an embodiment.
  • 67 is a diagram for describing a change in FF according to a phase difference between driving signals according to an exemplary embodiment.
  • 68 is a diagram for describing a change in FF according to a phase difference between driving signals according to an exemplary embodiment.
  • 69 is a flowchart illustrating obtaining an image having a high FF by adjusting a phase of a driving signal according to an exemplary embodiment.
  • FIG. 70 is a diagram for describing a change in a path of light according to a change in a phase of a driving signal according to an exemplary embodiment.
  • 71 is a view for explaining that the phase of a driving signal is changed and positions where light patterns pass are overlapped according to an exemplary embodiment.
  • 72 is a flowchart illustrating generating one image by using acquired values while changing a phase of a driving signal according to an exemplary embodiment.
  • 73 is a flowchart for explaining generating one image using acquired values while changing a phase of a driving signal to become a predetermined FF, according to an exemplary embodiment.
  • an optical fiber having a fixed end and a free end;
  • a first actuating unit configured to apply a first force on an actuator position between the fixed end and the free end of the optical fiber to guide the free end of the optical fiber to drive in a first direction;
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is disposed at a first rod position on the optical fiber, , The second end is disposed at a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the The first rod position of the optical fiber from the first end of the deformable rod, on a cross-section perpendicular to the longitudinal direction of the optical fiber and arranged parallel to the optical fiber from the first rod position to the second rod position
  • the angle between the virtual line connected to and the first direction is arranged to be within a preset range, so that the free
  • an optical fiber having a fixed end and a free end;
  • a first actuating unit configured to apply a first force on an actuator position between the fixed end and the free end of the optical fiber to guide the free end of the optical fiber to drive in a first direction;
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is disposed at a first rod position on the optical fiber, , The second end is disposed at a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the The first rod position of the optical fiber from the first end of the deformable rod, on a cross-section perpendicular to the longitudinal direction of the optical fiber and arranged parallel to the optical fiber from the first rod position to the second rod position
  • the angle between the virtual line connected to and the first direction is arranged to be within a preset range, so that the free end of the
  • a second actuating unit configured to apply a second force to the actuator position of the optical fiber; further comprising, the second actuating unit a second actuating unit having a free end of the optical fiber perpendicular to the first direction. Can be induced to drive in any direction.
  • the optical fiber may have a first rigidity
  • the deformable rod may have a second rigidity
  • the deformable rod may change the rigidity of the optical fiber in at least one of the first direction and the second direction when the optical fiber is driven according to the first force and the second force.
  • the optical fiber may perform resonance driving according to different resonance frequencies with respect to the first direction and the second direction.
  • the length of the deformable rod may be shorter than the length of the optical fiber.
  • first end of the deformable rod is fixed to the first rod position on the optical fiber by a first connector
  • second end is fixed to the second rod position on the optical fiber by a second connector
  • first connector and the second connector may move together according to the vibration of the optical fiber.
  • control unit for applying a first driving frequency to the first actuating unit, and applying a second driving frequency to the second actuating unit.
  • first driving frequency and the second driving frequency may have a difference of more than a predetermined range.
  • an image generating apparatus comprising an irradiation unit for irradiating light to an object, a light receiving unit for receiving a signal returned from the object, and a control unit for generating an image based on a signal obtained from the light receiving unit, the fixed end and An optical fiber having a free end; It is located at an actuator position between the fixed end and the free end of the optical fiber, and is configured to apply a first force on the actuator position to induce the free end of the optical fiber to resonantly drive in a first direction.
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is fixed at a position of the first rod on the optical fiber , The second end is fixed to a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the Arranged in parallel with the optical fiber from the first rod position to the second rod position, the deformable rod has a free end of the optical fiber in the first direction according to the first force applied from the first actuating part.
  • An image generating apparatus may be provided in which an angle between a virtual line connected to the first rod position of the optical fiber from the first end of the rod and the first direction is within a preset range.
  • an optical fiber having a fixed end and a free end; A first positioned at an actuator position between the fixed end and the free end of the optical fiber and configured to apply a first force on the actuator position to induce the free end of the optical fiber to drive in a first direction Actuating unit; A second actuating unit configured to apply a second force to the actuator position of the optical fiber to guide the free end of the optical fiber to drive in a second direction perpendicular to the first direction; A control unit for applying a first driving signal to the first actuating unit and a second driving signal to the second actuating unit; And a deformable rod disposed adjacent to the optical fiber and having a first end and a second end, wherein the first end of the deformable rod is disposed at a first rod position on the optical fiber, , The second end is disposed at a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the The first rod
  • control unit may apply the same voltage to the first actuating unit and the second actuating unit so that the optical fiber irradiates scanning patterns having different ratios with respect to the first direction and the second direction. have.
  • control unit may apply a voltage greater than that of the second actuating unit to the first actuating unit to irradiate a scanning pattern having a one-to-one ratio with respect to the first direction and the second direction.
  • the control unit As the optical fiber vibrates by the first force applied from the first actuating unit and the second force applied from the second actuating unit, the control unit generates a Lisaju pattern meeting a preset standard. You can control it to draw.
  • first driving frequency and the second driving frequency may have a difference of more than a preset range.
  • first end of the changeable rod is fixed in the first rod position on the optical fiber by a first connector
  • second end is fixed in the second rod position on the optical fiber by a second connector
  • first connector and the second connector may move together according to the vibration of the optical fiber.
  • the changeable rod is, on a cross-section perpendicular to the length direction of the optical fiber, between the first direction and a virtual line connected from the first end of the changeable rod to the first rod position of the optical fiber
  • the angle of Vibration of the free end in the second direction may be limited.
  • the optical fiber may have a first rigidity
  • the deformable rod may have a second rigidity
  • the deformable rod may change the rigidity of the optical fiber in at least one of the first direction and the second direction when the optical fiber is resonantly driven according to the first force and the second force.
  • an optical fiber having a fixed end and a free end; A first positioned at an actuator position between the fixed end and the free end of the optical fiber and configured to apply a first force on the actuator position to induce the free end of the optical fiber to drive in a first direction Actuating unit; A second actuating unit configured to apply a second force to the actuator position of the optical fiber to guide the free end of the optical fiber to drive in a second direction perpendicular to the first direction; A housing for accommodating the optical fiber and the first and second actuating parts; a mass body having a predetermined size is attached between the fixed end and the free end of the optical fiber, and the mass body includes the optical fiber having the first force and When the second force vibrates, the mass body is attached within a collision avoidance distance range adjacent to the free end side of the optical fiber to prevent damage by colliding with the inner wall of the housing, and the collision prevention distance range includes the optical fiber.
  • An optical device in which at least one of the maximum driving range of the optical fiber from the center of the housing inner diameter and the
  • a deformable rod disposed adjacent to the optical fiber and having a first end and a second end; further comprising, the first end of the deformable rod is fixed at a position of the first rod on the optical fiber, and the A second end is fixed to a second rod position on the optical fiber, the first rod position and the second rod position on the optical fiber are between the actuator position and the free end, and the deformable rod is at least the first It may be disposed in parallel with the optical fiber from the load position to the second load position.
  • the deformable rod is, on a cross section perpendicular to the length direction of the optical fiber, between the first direction and a virtual line connected from the first end of the changeable rod to the first rod position of the optical fiber.
  • the angle of is arranged to be within a preset range, and when the free end of the optical fiber is driven in the first direction according to the first force applied by the first actuating unit to the actuator position of the optical fiber, the second It can limit vibration in the direction.
  • first end of the deformable rod is fixed at the position of the first rod on the optical fiber by a first fixing element
  • the second end is at the position of the second rod on the optical fiber by a second fixing element. Can be fixed.
  • control unit for applying a first driving frequency to the first actuating unit and applying a second driving frequency to the second actuating unit may be further included.
  • first driving frequency and the second driving frequency may have a difference of more than a preset range.
  • the size of the mass body may be designed to resonately drive the optical fiber with a predetermined amplitude in the first direction and the second direction.
  • mass body may be attached to the second rod position so that the second end of the deformable rod is fixed on the optical fiber.
  • the second rod position may be determined such that the optical fiber has different resonant frequencies with respect to the first direction and the second direction.
  • an apparatus for irradiating light to an object comprising: a control module that generates driving signals; and an irradiator configured to receive the driving signals from the control module and irradiate light to the object based on the driving signals ; And a first driving signal having a first driving frequency and a first phase among the driving signals, and a second driving signal having a second driving frequency and a second phase.
  • a third driving signal having a first driving frequency and a third phase and a fourth driving signal having a second driving frequency and a fourth phase are applied to the irradiation unit.
  • control module includes a phase difference between the first phase and the second phase and a phase difference between the third phase and the fourth phase n times a predetermined phase.
  • An optical device may be provided that generates the first to fourth drive signals to make a difference.
  • the optical device in order to obtain light returning from the object, and to obtain an image of the object using the obtained light, receive light returning from the object, and A light-receiving unit that generates light-receiving information representing information, wherein the control module acquires a first data set by using light returned from the object according to the first scanning pattern, and Acquiring a second data set using light returned from the corresponding object, obtaining a third data set using the first data set and the second data set, and the object based on the third data set You can create an image for
  • a plurality of regions and irradiation light information corresponding to each of the plurality of regions are defined from the third data set, and a plurality of regions defined from the third data set among a plurality of predetermined regions of an image of the object
  • the first fill factor indicating the degree to be included may be equal to or greater than a predetermined level.
  • the first fill factor may be 100%.
  • the predetermined phase is the first driving frequency or the second driving It can be based on the frequency and the number of a plurality of predetermined areas when the optical device is irradiated with light.
  • the predetermined phase may be determined by Equation (a).
  • the predetermined phase may be determined by Equation b.
  • n is the first driving frequency or the second driving frequency
  • the maximum common divisor of the first driving frequency and the second driving frequency and a plurality of predetermined regions may be obtained.
  • n may be determined by Equation c.
  • GCD represents the maximum common divisor of the first driving frequency and the second driving frequency, Represents the first driving frequency, and pixel represents the number of the predetermined plurality of regions
  • n may be determined by Equation d.
  • GCD represents the maximum common divisor of the first driving frequency and the second driving frequency, Represents the second driving frequency, and pixel represents the number of the predetermined plurality of regions
  • a control module for generating driving signals the control module for irradiating light to an object, obtaining light returning from the object, and obtaining an image of the object using the obtained light
  • the method of generating a pattern in an optical device including an irradiator for receiving the driving signals from and irradiating light to the object based on the driving signals comprising: a first driving frequency and a first phase among the driving signals When a first driving signal and a second driving signal having a second driving frequency and a second phase are applied to the irradiating unit, irradiating light from the irradiating unit according to a first scanning pattern; When a third driving signal having a first driving frequency and a third phase among the driving signals and a fourth driving signal having a second driving frequency and a fourth phase is applied to the irradiating unit, the irradiating unit is applied to the second scanning pattern.
  • the control control module generates the first to fourth driving signals such that a phase difference between the first phase and the second phase and a phase difference between the third phase and the fourth phase are n times a predetermined phase difference.
  • a light irradiation method comprising; may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information To obtain a plurality of data sets, and determine a data set for obtaining an image of good quality according to a predetermined criterion among the plurality of data sets, the plurality of data sets being the first of the first signal A phase-adjusted data set obtained when at least one of a phase component or the second phase component of the second signal is adjusted, and the image of the object uses the determined data set among the plurality of data sets
  • an image generating device that is generated may be provided.
  • the light-receiving information may include light intensity values corresponding to positions of a plurality of pixels determined by the first signal and the second signal.
  • each of the plurality of data sets includes a light intensity value corresponding to a position of a plurality of pixels, and in each of the plurality of data sets, a light intensity value corresponding to a position of at least some of the positions of the plurality of pixels Is a plurality, and the control module determines a data set for obtaining an image of good quality based on a difference value between a plurality of light intensity values corresponding to each of the positions of the at least some pixels among the plurality of data sets. I can.
  • control module comprises, among the plurality of data sets, a data set having the least sum of difference values between a plurality of light intensity values corresponding to each of the positions of the at least some pixels for obtaining the good quality image. Can be determined by data set.
  • the difference value between the plurality of light intensity values may be a dispersion between the plurality of light intensity values.
  • a difference value between the plurality of light intensity values may be a standard deviation between the plurality of light intensity values.
  • the plurality of data sets includes a first data set and a second data set
  • the first data set includes a 1-1 light intensity value and a first light intensity value corresponding to a first pixel position among the plurality of pixel positions.
  • the second data set includes positions of a plurality of pixels
  • the 1-1 light intensity value and the 1-2 light intensity value corresponding to the location of the first pixel, and the 2-1 light intensity value and the 2-2 light intensity value corresponding to the location of the second pixel among the locations of the plurality of pixels Including a light intensity value, wherein the predetermined criterion for determining the good quality image is a difference value between the first-first light intensity value corresponding to the first pixel position and the first-second light intensity value And a difference value between the 2-1 light intensity value and the 2-2 light intensity value corresponding to the location of the second pixel, and the control module
  • the plurality of data sets includes a first data set and a second data set, the first data set is generated using the first signal, the second signal, and the light-receiving information, and the second data
  • the set may be generated by using the first signal, the second signal, and the light-receiving information for which the phase component is adjusted.
  • the plurality of data sets includes a first data set and a second data set, the first data set is generated using the first signal, the second signal, and the light-receiving information, and the second data
  • the set may be generated using the first signal, the second signal to which the phase component is adjusted, and the light reception information.
  • the plurality of data sets includes a first data set and a second data set
  • the first data set includes a signal in which a phase component of at least one of the first signal or the second signal is changed and the light-receiving information
  • the second data set may be generated by using a signal in which a phase component of at least one of the first signal or the second signal is changed and the light-receiving information.
  • the second data set may change a light intensity value according to the light reception information corresponding to a plurality of pixel positions according to the phase adjustment.
  • first axis direction and the second axis direction may be orthogonal to each other, and the first axis direction may represent an x-axis of a Cartesian coordinate system, and the second axis direction may represent a y-axis of the orthogonal coordinate system.
  • the first signal when the first phase component of the first signal is adjusted, the first signal, whose phase is not adjusted, is applied to the scanning unit, and the phase-adjusted first signal is the phase-adjusted data set Can be used in the creation of.
  • the scanning unit may irradiate the light in a predetermined pattern as the first signal and the second signal are applied.
  • control module may determine the adjusted phase component corresponding to the image generated using the phase-adjusted data set as a final correction phase for correcting the first signal or the second signal.
  • a control module in an image generation method of obtaining an image of an object by irradiating light, a control module generates a first signal having a first frequency component and a first phase component in a first axis direction, and a second axis Generating a second signal having a second frequency component and a second phase component in a direction; Irradiating light to the object by using the first signal and the second signal by a scanning unit; And acquiring light-receiving information from the light returned from the object according to the light irradiated by the scanning unit in the light receiving unit, wherein the control module includes: the first signal, the second signal, and the A plurality of data sets are obtained using light-receiving information, and a data set for obtaining a good quality image according to a predetermined criterion is determined among the plurality of data sets, and the plurality of data sets A phase-adjusted data set obtained when at least one of a first phase component or the second phase component of the second signal is adjusted, and
  • the image generating apparatus in an image generating apparatus to irradiate light to an object by using a Lisaju pattern and acquire an image of the object based on the returned light, includes a control module, a driving unit, and a scanning unit. And a light receiving unit, wherein the control module includes a first driving signal, a second frequency component, and a second phase component including a first frequency component and a first phase component in order to irradiate light to the object according to a Lissajous pattern.
  • a driving signal including a second driving signal including a second driving signal is applied to a driving unit, and the driving unit receives the driving signal from the control module, and the scanning unit receives a first scanning unit output signal and a second output signal corresponding to the first driving signal.
  • the light receiving unit acquires the intensity of light returned from the object based on the light irradiated by the scanning unit
  • the control module includes the first driving signal and the second driving signal and the In order to correct that the phase components of the output signal of the first scanning unit and the output signal of the second scanning unit are different from each other, a difference in the phase component between the first driving signal and the output signal of the first scanning unit occurs, and the second driving
  • the control module uses the first driving signal, the second driving signal, and the intensity of the light obtained through the light receiving unit to set the first data.
  • a data set having a small difference in phase component between output signals of the ning unit may be determined, and the determined data set may be provided with an image generating apparatus used to generate an image of an object.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module comprises: a position of a first signal-corresponding pixel-the first signal-corresponding pixel The position is obtained based on the first signal and the second signal-A first data set is obtained based on the signal and the light-receiving information, and at least one of signals corresponding to the pixel position corresponding to the first signal A phase component is changed by a first phase change period, and a second data set is obtained based on a second signal-corresponding pixel position based on a change in the phase component, and the second data set is a predetermined value compared to the first data set.
  • At least one phase component of the phase components of the signals corresponding to the position of the second signal corresponding pixel is changed by the first phase change period, and the third signal-corresponding pixel based on the change in the phase component
  • a third data set is obtained based on a position and the second data set more meets a predetermined criterion than the third data set
  • a reconstructed pixel position image for the object is generated based on the second data set.
  • the preset phase change period is a fill factor according to signals corresponding to the first data set.
  • the fill factor indicates a degree occupied by an area irradiated with light from the image generating apparatus among a plurality of predetermined areas.
  • Indicate-and a fill factor according to signals corresponding to the second data set may be set to correspond.
  • control module may obtain at least one candidate phase based on a phase component of signals corresponding to the second data set for generating an image of the object, and correspond to each of the at least one candidate phase. Acquire at least one candidate data set, select a candidate data set that best meets the predetermined criterion from among the at least one candidate data set, and generate an image of the object based on the selected candidate data set. have.
  • the control module at least one phase component of the signals corresponding to the position of the pixel corresponding to the second signal is changed by a second phase change period, and based on the position of the fourth signal corresponding pixel based on the change of the phase component.
  • the fourth data set is obtained by using the method, and the fourth data set more meets a predetermined criterion than the second data set
  • at least one phase component of the signals corresponding to the pixel position corresponding to the fourth signal is the The fifth data set is changed by a second phase change period, and a fifth data set is obtained based on a fifth signal-corresponding pixel position based on a change in the phase component, and the fourth data set more meets a predetermined criterion than the fifth data set. If so, an image of the object may be generated based on the fourth data set.
  • control module the signal corresponding to the first data set, the first phase angle component of the first signal-The first phase angle component is based on the first frequency component and the first phase component -This substantially 90 degree changed signal and the second phase angle component of the second signal-the second phase angle component is based on the second frequency component and the second phase component-this substantially 90 degree changed signal Can include.
  • control module compares the first frequency component with the second frequency component, and when the first frequency component is smaller than the second frequency component, the first of the signals corresponding to the first data set
  • a phase component of a signal having a frequency component is changed by the first phase change period, and the second frequency component is smaller than the first frequency component, a second frequency component among signals corresponding to the first data set is
  • the phase component of the possessed signal may be changed by the first phase change period.
  • the pixel positions corresponding to the first phase signal of the first data set include a plurality of first identical pixel positions and a plurality of second identical pixel positions, and the light-receiving information includes each of the plurality of first identical pixel positions.
  • light intensity values corresponding to each of the plurality of second identical pixel positions, and the second phase signal corresponding pixel positions of the second data set include a plurality of third identical pixel positions and Includes a plurality of fourth identical pixel positions
  • the light-receiving information includes light intensity values corresponding to each of the plurality of third identical pixel positions and light intensity values corresponding to each of the plurality of fourth identical pixel positions
  • the control module the difference value between the light intensity values corresponding to each of the plurality of first identical pixel positions and the sum of the difference values between the light intensity values corresponding to each of the plurality of second identical pixel positions Obtaining a first sum and representing a sum of difference values between light intensity values corresponding to each of the plurality of third identical pixel positions and a difference value between light intensity values corresponding to each of the plurality of fourth identical pixel positions
  • a difference value between light intensity values corresponding to each of the plurality of identical pixel positions may be a standard deviation between light intensity values corresponding to each of the plurality of identical pixel positions.
  • control module may obtain a difference value between phase components of signals corresponding to the second data set, and use the difference value between the phase components and a preset phase change value to determine the first signal or the first signal.
  • the preset phase change value is substantially half of an odd multiple of the preset phase change period when both the first frequency component and the second frequency component are odd numbers and based on the preset phase change period Is determined, and when only one of the first frequency component and the second frequency component is an even number, it may be determined based on substantially half of an even multiple of the preset phase change period and the preset phase change period. have.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information A first data set is obtained by using, and the phase component of at least one signal among the first signal or the second signal is changed a plurality of times by a first phase change period, and each signal and light received by the plurality of times are changed.
  • n is an integer greater than or equal to 2-At least one signal in which the phase component is changed n times by the first phase change period and the light reception
  • the n-th data set is obtained by using information, and the n-1-th data set is obtained before the n-th data set-The n-th data set is at least one of the first signal or the second signal.
  • the phase component of the signal is changed n-1 times by the first phase change period-If the n-th data set meets a predetermined criterion, at least one of the first signal or the second signal N+1th data using at least one signal in which the phase component of is changed n+1 times by the first phase change period and the phase component is changed n+1 times by the first phase change period and the light reception information
  • the phase component is based on at least one signal changed n-1 times by the first phase change period
  • An image generating device for generating a raw image may be provided.
  • At least one signal that is changed by the first phase change period is a first signal having the first frequency and the first phase component
  • the control module includes the phase component of the second signal being the first
  • the m-th data set is obtained by using the second signal and the light reception information in which the phase component is changed m times by the first phase change period, and the The m-1th data set acquired prior to the mth data set-The m-1th data set is generated when the phase component of the second signal is changed m-1 times by the first phase change period-More above
  • the phase component of the second signal is changed m+1 times by the first phase change period, and the phase component is m+1 times by the first phase change period.
  • the phase component is the first
  • An image may be generated based on the second signal that has been changed m-1 times by the phase change period.
  • any one data set among the acquired data sets includes a plurality of first identical pixel positions and a plurality of second identical pixel positions
  • the light-receiving information included in the one data set is the plurality of The other one including light intensity values corresponding to each of the first identical pixel positions and light intensity values corresponding to each of the plurality of second identical pixel positions, except for the one data set among the acquired data sets
  • the data set of includes a plurality of third identical pixel positions and a plurality of fourth identical pixel positions
  • the light-receiving information included in the other data set is light corresponding to each of the plurality of third identical pixel positions.
  • the control module includes a difference value between the light intensity values corresponding to each of the plurality of first identical pixel positions and the plurality of A first sum indicating the sum of the difference values between the light intensity values corresponding to each of the second same pixel positions of is obtained, and the difference value between the light intensity values corresponding to each of the plurality of third identical pixel positions and the plurality of Obtaining a second sum representing the sum of the difference values between the light intensity values corresponding to each of the fourth identical pixel positions of, and when comparing the first sum and the second sum, when the second sum is smaller, It may be determined that the other data set more meets the predetermined criterion than the one data set.
  • a difference value between light intensity values corresponding to each of the plurality of identical pixel positions may be a standard deviation between light intensity values corresponding to each of the plurality of identical pixel positions.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component;
  • a scanning unit irradiating light to the object using the first signal and the second signal;
  • a light-receiving unit for acquiring light-receiving information based on light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes a predetermined value in the first phase component of the first signal.
  • an image generating apparatus may be provided that generates an image by using the first data set obtained based on the first phase change signal.
  • any one data set among the acquired data sets includes a plurality of first identical pixel positions and a plurality of second identical pixel positions
  • the light-receiving information included in the one data set is the plurality of The other one including light intensity values corresponding to each of the first identical pixel positions and light intensity values corresponding to each of the plurality of second identical pixel positions, except for the one data set among the acquired data sets
  • the data set of includes a plurality of third identical pixel positions and a plurality of fourth identical pixel positions
  • the light-receiving information included in the other data set is light corresponding to each of the plurality of third identical pixel positions.
  • the control module includes a difference value between the light intensity values corresponding to each of the plurality of first identical pixel positions and the plurality of A first sum indicating the sum of the difference values between the light intensity values corresponding to each of the second same pixel positions of is obtained, and the difference value between the light intensity values corresponding to each of the plurality of third identical pixel positions and the plurality of Obtaining a second sum representing the sum of the difference values between the light intensity values corresponding to each of the fourth identical pixel positions of, and when comparing the first sum and the second sum, when the second sum is smaller, It may be determined that the other data set more meets the predetermined criterion than the one data set.
  • a difference value between light intensity values corresponding to each of the plurality of identical pixel positions may be a standard deviation between light intensity values corresponding to each of the plurality of identical pixel positions.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes: the first signal, the second signal, and the light-receiving information A first data set is obtained based on, and a second data set obtained by changing signals corresponding to the first data set by a preset phase change period is obtained, and the second data set is predetermined compared to the first data set.
  • a third data set obtained by changing signals corresponding to the second data set by the preset phase change period is obtained, and the second data set is a predetermined criterion than the third data set. If it is more consistent with, an image generating apparatus for generating an image of the object based on the second data set may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a first signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component;
  • a scanning unit irradiating light to the object using the first signal and the second signal;
  • a light-receiving unit for acquiring light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module comprises: the first signal and the second signal at a first time point.
  • a first image is generated and output using, and the phase of at least one of the first signal and the second signal is changed during a predetermined time period after the first time point, and after the predetermined time period Generates and outputs a second image using at least one signal whose phase has been changed at a second time point, wherein the phase of the first signal at the first time point and the phase of the first signal at the second time point
  • the difference and the difference between the phase of the second signal at the first time point and the phase of the second signal at the second time point is substantially an integer multiple difference based on a predetermined phase change period, and the predetermined phase change
  • An image generating apparatus may be provided in which a period is determined based on the first frequency component and the second frequency component.
  • generating a first signal having a first frequency component and a first phase component in a first axis direction, and generating a second signal having a second frequency component and a second phase component in a second axis direction A control module, a scanning unit that irradiates light to the object using the first signal and the second signal, and acquires light reception information by light returned from the object according to the light irradiated by the scanning unit
  • An image generating method of an image generating apparatus including a light receiving unit and irradiating light to obtain an image of an object, wherein the control module includes a first signal-corresponding pixel position-the first signal-corresponding pixel position is the first signal and the Obtained based on a second signal-obtaining a first data set based on a signal and the light received information; At least one phase component of the signals corresponding to the position of the pixel corresponding to the first signal is changed by a first phase change period, and a second data set is obtained based on the position of the pixel corresponding to the first signal
  • At least one phase component of the phase components of signals corresponding to the pixel position corresponding to the second signal is the first phase change period A step that is changed by; And obtaining a third data set based on a third signal-corresponding pixel position based on a change in the phase component, and if the second data set more meets a predetermined criterion than the third data set, the second data set.
  • An image generation method including; generating an image of the object based on may be provided.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a second frequency component and a second signal are generated in a second axis direction.
  • a control module for generating a second signal having a phase component; and a scanning unit for irradiating light to the object using the first signal and the second signal, wherein the control module includes a pixel corresponding to a first signal
  • a first data set is obtained based on a location-the location of the pixel corresponding to the first signal is obtained based on the first signal and the second signal, and at least one of the signals corresponding to the location of the pixel corresponding to the first signal
  • One phase component is changed by a first phase change period, and a second data set is obtained based on a second signal-corresponding pixel position based on a change in the phase component, and the second data set is greater than the first data set.
  • At least one phase component of the phase components of the signals corresponding to the position of the pixel corresponding to the second signal is changed by the first phase change period, and a third signal based on the change of the phase component If a third data set is obtained based on a corresponding pixel position, and the second data set more meets a predetermined criterion than the third data set, the position of light irradiated to the object based on the second data set and A light irradiation device may be provided to determine the location of the pixel so that the location of the pixel corresponding to the second signal corresponds.
  • a mounting device for mounting an image generating device comprising a probe, irradiating light to an object at one end of the probe, and receiving light returned from the object at the one end, the image A housing containing at least a portion of the generating device, the at least part comprising the one end;
  • phase correction of a driving signal for determining a position at which light is irradiated to the object from the one end is performed, at least one A reference image providing unit providing a reference image; wherein the reference image providing unit is an image in which a position of the reference image is adjusted such that a distance between one end of the probe and the reference image is adjusted to a focal length of the probe
  • a mounting device for mounting the generating device may be provided.
  • a mounting device for mounting an image generating device comprising a probe, irradiating light to an object at one end of the probe, and receiving light returned from the object at the one end, the image A housing containing at least a portion of the generating device, the at least part comprising the one end;
  • a plurality of references may be performed to perform phase correction of a driving signal that determines a position at which light is irradiated to the object from the one end.
  • a reference image providing unit for providing an image wherein the reference image providing unit comprises: a plurality of reference images in which each of the plurality of reference images is arranged such that a distance between one end of the probe and the reference image is adjusted to a focal length of the probe.
  • a mounting device for mounting an image generating device including a layer of may be provided.
  • it may further include an adjustment unit for adjusting the position of the reference image providing unit so that the distance between the one end of the probe and the reference image is adjusted to the focal length of the probe.
  • the reference image may use a reflective material so that a reflected signal may be used when scanning is performed.
  • the reference image providing unit may further include a cartridge for providing a fluorescent material to the reference image.
  • the cartridge may include at least one of fluorescent materials expressed as signals in wavelength bands of 405 nm, 488 nm, 630 nm, and 785 nm.
  • the cartridge may include at least one of fluorescent materials expressed as signals in wavelength bands of 405 nm, 488 nm, 630 nm, and 785 nm.
  • it may further include a fixing part for allowing the probe to be coupled to the probe mounting device at a predetermined angle.
  • At least one layer of the reference image providing unit may include providing a reference image in a transparent material.
  • the reference image may be a circular pattern.
  • a first signal having a first frequency component and a first phase component is generated in a first axis direction, and a first signal is generated in a second axis direction.
  • a control module generating a second signal having two frequency components and a second phase component; A scanning unit irradiating light to the object using the first signal and the second signal; And a light-receiving unit for obtaining light-receiving information according to light returned from the object according to the light irradiated by the scanning unit, wherein the control module includes an input signal input to the scanning unit and the scanning unit operating In order to correct the phase difference between the actual signals, phase correction is performed on the input signal, but the scanning unit is mounted on the mounting device-the mounting device has a reference image disposed therein-and the mounting from the scanning unit When light is irradiated toward the reference image disposed inside the device, first-order phase correction is performed on the input signal using light-receiving information based on light returned from the reference image, and the scanning unit When light is irradiated from the scanning unit toward the object without being mounted, a second-order phase correction is repeatedly performed on the input signal at predetermined periods using a light-receiving signal based on
  • the first-order phase correction is obtained by the control module based on the light-receiving signal obtained from the reference image by comparing the reference image and the image obtained by the control module based on the light-receiving signal obtained from the reference image.
  • the phase may be corrected so that one image matches the reference image.
  • the secondary phase correction is predicted that the quality of an image will be good when a plurality of data sets are acquired using the first signal, the second signal, and the light-receiving information, and images are imaged among the plurality of data sets.
  • Determining a data set, wherein the plurality of data sets comprises a phase-adjusted data set obtained when at least one of the first phase component of the first signal or the second phase component of the second signal is adjusted.
  • the image of the object is generated using the determined data set among the plurality of data sets
  • the predetermined criterion includes a light intensity value corresponding to a position of a plurality of pixels in each of the plurality of data sets.
  • the positions of the at least some of the pixels of the plurality of data sets are respectively It may be determined whether a predetermined criterion is met based on a difference value between a plurality of light intensity values.
  • the image generating apparatus may drive the scanning unit until the second-order phase correction is performed.
  • generating a first signal having a first frequency component and a first phase component in a first axis direction, and generating a second signal having a second frequency component and a second phase component in a second axis direction A control module, a scanning unit that irradiates light to the object using the first signal and the second signal, and acquires light reception information by light returned from the object according to the light irradiated by the scanning unit
  • a phase correction method of an image scanning apparatus including a light receiving unit and irradiating light to obtain an image of an object, wherein the phase difference between an input signal input to the scanning unit and an actual signal operated by the scanning unit is corrected, the Performing, by a control module, phase correction on the input signal; Including, the step of performing the phase correction, in a state where the scanning unit is mounted on the mounting device-the mounting device has a reference image disposed therein-the reference image disposed inside the mounting device from the scanning unit Performing a first-order phase correction on the input signal by using light-rece
  • the "image generating device” is a reflected image (RI), a fluorescence image (FI), and a transmitted image (TI) of an object in real time. ) May be an optical device for obtaining and providing at least one of.
  • the image generating apparatus may include various types of endomicroscopes for directly observing or diagnosing a pathological condition of a living body in real time.
  • Microscopic microscopes are optical microscopes based on lasers such as confocal, two-photon, and OCT.
  • a confocal microscope uses a pinhole to block out-of-focus light and focus only the light passing through the pinhole on an objective lens to perform imaging in pixel units.
  • a confocal laser scanning microscope that applies a laser to a sample and generates light of a certain wavelength to receive only precisely focused light through a detector and convert it into a digital signal for observation.
  • CLSM a confocal laser scanning microscope
  • the confocal laser scanning microscope focuses on a sample with a laser beam, and can generate an image using fluorescence, reflected light, and transmitted light generated from the sample.
  • autofluorescence generated by a specific substance in the sample or a fluorescent image may be observed by injecting a fluorescent substance into the sample.
  • the image generating apparatus may include a laser microscanner for accurately observing or diagnosing an object in real time.
  • Laser micro-scanners can be typically classified into MEMS (Micro Electric Mechanical System) scanners using a semiconductor process method and optical fiber scanners using optical fibers.
  • MEMS Micro Electric Mechanical System
  • laser micro-scanners can be classified into side-viewing, circumferential-viewing, and forward-viewing.
  • MEMS scanners include mirror scanners and lens scanners that reflect laser light, and mainly perform side-side imaging.
  • the MEMS scanner has a disadvantage in that compact packaging is difficult because an additional device for bending the beam bent by the mirror is required for front side imaging.
  • the optical fiber scanner is driven using an actuator such as a piezoelectric element, so that packaging is simpler and more compact packaging is possible than a MEMS mirror scanner.
  • the optical fiber scanner since the optical fiber scanner is driven at the resonant frequency of the optical fiber, it has the advantage of implementing a wide field of view (FOV) with a relatively low voltage.
  • FOV field of view
  • the above-described image generating apparatuses may be used in various fields for obtaining a fluorescence image, a reflection image, a transmission image, etc. of an object as a 2D or 3D image.
  • the image generating device may be used to observe and diagnose an image of an object in real time in fields such as biology research, disease diagnosis, endoscopic surgery, and the like.
  • the image generating device may be used to measure the remaining life of the metal structure to be inspected based on the degree of cracks, holes, and creeps in the metal facility.
  • the image generating apparatus may be applied to a LiDAR apparatus that generates 3D stereoscopic information by measuring an optical distance returned by reflecting a laser beam and performing dispersion scanning.
  • FIG. 1 is a diagram illustrating an environment in which an image generating device according to an exemplary embodiment of the present application is used.
  • the image generating apparatus 1 may generate an image in real time by scanning of an object O.
  • the image generating apparatus 1 may be a microscopic optical fiber scanner for observing a pathological state of a living tissue in real time in a laboratory or an operating room.
  • the image analysis device 2 may be a device for performing a pathological diagnosis in real time using an image generated by the image generating device 1.
  • the image analysis device 2 may be an electronic device assigned to a medical technician capable of performing a pathological diagnosis.
  • the image analysis device 2 may be provided in the form of a module inside an electronic device assigned to a medical technician capable of performing a pathological diagnosis.
  • the image generating device 1 and the image analyzing device 2 may be connected through a network N.
  • the network N may include various wired or wireless networks, and the image generating device 1 and the image analyzing device 2 may transmit and receive various types of information through the network.
  • the image generating device 1 may transmit an image generated by the image generating device 1 to the image analyzing device 2 in real time through a network N.
  • the image analysis device 2 is provided in the form of a module in an electronic device allocated to a medical technician, the image analysis device 2 is based on an image transmitted in real time from the image generating device 1. It may be a program or software application for performing pathological diagnosis.
  • a medical technician may diagnose cancer and determine an operation site based on a biometric image displayed on the electronic device.
  • a medical technician may input information related to cancer diagnosis, surgery site determination, and the like through an application executed on the electronic device.
  • the image analysis device 2 may automatically diagnose cancer and determine an operation site based on a previously stored image analysis program.
  • the image analysis device 2 may store a machine learning algorithm in which criteria related to cancer diagnosis and surgery site determination are learned in advance.
  • the image analysis device 2 merges or maps information related to cancer diagnosis or surgery site determination to an image received from the image generating device 1 to provide the image generating device 1 or other electronic device. It can be transmitted to a device (not shown).
  • FIG. 2 is a block diagram illustrating an exemplary configuration of an image generating apparatus according to an exemplary embodiment of the present application.
  • the image generating apparatus 1 may include a scanning module 110, a control unit 130, and an optical module 120.
  • the scanning module 110 may irradiate light to the object while in contact with the object or while being spaced apart by a predetermined distance. Accordingly, the scanning module 110 may measure the interior within a preset distance from the surface of the object.
  • the preset distance may be changed by adjusting the focal length of the lens module to be described later, and may be 0um to 250um.
  • the scanning module 110 may be a fixed device or a handheld type optical device.
  • the handheld type scanning module 110 may be implemented in the form of an endoscope or a pen type.
  • the scanning module 110 may be a pen-type optical device.
  • the user may directly contact the object to be observed or the optical device around the object, and the scanning module 110 may measure the inside of the object at a preset distance from the object surface.
  • the scanning module 110 may be an endoscope microscope used in a hospital.
  • the medical professional may contact the scanning module 110 on the skin surface of the patient, and the scanning module 110 may measure the state of the superficial cells at a depth of 50 ⁇ m from the contact surface.
  • a medical professional may contact the scanning module 110 with a part of the patient's body open to diagnose cancer or determine an operation site, and the scanning module 110 may be at a depth of 70 ⁇ m from the contact surface. It is possible to measure the internal tissue of the living body in real time.
  • a fluorescent dye may be injected in advance in the form of an injection in order to effectively check the pathological state of the tissue inside the living body.
  • the scanning module 110 may irradiate light to the object, and the optical module 120 to be described later may detect a fluorescence signal returned from the object.
  • the scanning module 110 may perform a scanning operation according to a driving signal applied from the controller 120 to be described later.
  • the scanning operation principle performed by the scanning module 110 will be described in detail in the following related embodiments.
  • the controller 130 may be a component for controlling the overall scanning operation of the scanning module 110 so that the scanning module 110 described above performs scanning according to a preset scanning pattern.
  • the controller 130 may apply a preset driving signal to the scanning module 110.
  • the preset driving signal may include frequency, voltage, phase, and the like.
  • control unit 130 may adjust the frequency, voltage, phase, etc. to change the irradiation range of light performed by the scanning module 110.
  • the controller 130 may control the scanning module 110 to perform a scanning operation based on a driving signal input from a user.
  • the preset scanning pattern may vary, and the controller 130 may apply a driving signal corresponding to the preset scanning pattern to the scanning module 110.
  • the scanning pattern may include spiral scanning, raster scanning, and Lisaju scanning.
  • spiral scanning is a scanning method that draws a part of a spiral, and the horizontal axis and the vertical axis are implemented at the same frequency.
  • raster scanning is a method of sequentially performing scanning in a horizontal direction, and there is a large difference in frequency between the horizontal axis and the vertical axis.
  • a relatively high voltage is required for a slow axis, and a frame rate may be lowered.
  • lissajous scanning is a pattern generated by intersections of two sinusoidal curves at right angles to each other, and the horizontal and vertical axes are implemented at different frequencies.
  • the frame rate can be at least 10 Hz.
  • the optical module 120 is an optical system that applies light to the scanning module 110 and detects a signal returned through the scanning module 110.
  • the optical module 120 may be a confocal microscope system, and the optical module 120 may be provided as a separate device separated from the scanning module 110 described above.
  • the optical module 120 may include at least a light irradiation unit 121 and a light receiving unit 123.
  • the light irradiation unit 121 may be a laser device that emits a laser signal of a preset wavelength band.
  • the laser device may be selected according to which image of a reflection image, a fluorescence image, and a transmission image of the object to be observed.
  • the laser device used in the embodiments of the present application may be one that emits a laser signal in a near-infrared region.
  • a laser signal may be of 405 nm, 488 nm, or 785 nm wavelength, depending on the fluorescent dye used.
  • fluorescent dyes may be used to distinguish pathological features of cells, blood vessels, tissues, etc. inside a living body, and dyes approved by ICG, FNa, 5-ALA, and other medical laws may be applied.
  • the light irradiation unit 121 may apply an appropriate laser source to the scanning module 110 based on a signal input from an optical module control device (not shown).
  • the optical module control device may control power of a laser signal emitted from the light irradiation unit 121, a gain of an image, and the like.
  • the power of the laser signal may be set to be irradiated to 1 mW or less.
  • the optical module control device may be provided as part of the above-described control unit 130.
  • the controller 130 may control the power of the laser signal emitted from the light irradiation unit 121, the gain of the image, and the like.
  • the light receiving unit 123 may be configured to detect a signal returned from the object for light irradiated from the above-described light irradiation unit 121 through the scanning module 110.
  • the signal detected by the light receiving unit 123 may be transmitted to the above-described control unit 130 or the image processing module 200 to be described later.
  • the controller 130 or the image processing module 200 may restore an image of an object based on a signal transmitted from the light receiving unit 123.
  • the image processing operation performed by the image processing module 200 will be described in detail in a related section below.
  • the image generating device 1 may further include an input unit 140.
  • the input unit 140 may be an input means for selecting an operation mode of the image generating device 1.
  • the operation mode may include at least a first mode and a second mode set in advance.
  • the first mode may be a low resolution mode or a search mode.
  • the second mode may be a high resolution mode or a zoom-in mode.
  • the user may select the first mode or the second mode according to the purpose of use and check an image having an appropriate resolution through the display device 300.
  • the input unit 140 may be an input means for selecting a working distance of the scanning unit 110.
  • the working distance may include a preset first distance, a second distance, a third distance, and the like, and an input means corresponding to the preset working distance may be further provided.
  • the working distance may correspond to a focal length of the lens module to be described later.
  • the controller 130 may perform a scanning operation of the scanning unit 110 and a calibration operation of an image generated by the scanning unit 110 according to the selected working distance.
  • input means corresponding to various functions for controlling the operation of the image generating apparatus 1 may be further provided.
  • FIG. 5 is a block diagram illustrating a configuration of an image processing module 200 according to an exemplary embodiment of the present application.
  • the image processing module 200 is a component for restoring an image of an object based on a signal transmitted from the light receiving unit 123.
  • the image processing module 200 may include a signal acquisition unit 210, a phase correction unit 220, an image restoration unit 230, and a data storage unit 240.
  • the signal acquisition unit 210 may be a component for acquiring a signal detected by the above-described light receiving unit 123.
  • the signal acquired by the signal acquisition unit 210 is a signal from which light irradiated to the object through the scanning module 110 returns through the scanning module 110 and may be defined as an output signal of the scanning unit.
  • the signal acquisition unit 210 may further perform an operation of converting an analog signal transmitted from the light receiving unit 123 into a digital signal.
  • a separate A/D conversion module (not shown) for converting the signal received by the signal acquisition unit 210 into a digital signal may be further provided.
  • the phase correction unit 220 is a component for correcting a phase difference generated in a process in which the driving signal applied to the scanning module 110 from the above-described control unit 130 is transmitted to the scanning module 110.
  • a phase difference over time may occur while a driving signal applied to the piezoelectric element is transmitted to the optical fiber.
  • a driving signal of the scanning unit actually driven by the optical fiber may be different from a driving signal applied to the piezoelectric element. Accordingly, a difference between the output signal of the scanning unit detected by the light receiving unit 123 and the driving signal applied to the piezoelectric element occurs.
  • image distortion by a predetermined phase difference may occur due to a difference between the output signal of the scanning unit and a driving signal applied to the piezoelectric element.
  • the phase difference may be changed in real time, and may be changed according to a change in the position of the scanning module 110.
  • a detector (not shown) for detecting a driving signal of a scanning unit in which the scanning module 110 is actually driven may be further installed inside the scanning module 110.
  • a phase difference according to a difference between a driving signal applied to the scanning module 110 and a driving signal of the scanning unit may be calculated.
  • the image processing module 200 may restore an image by reflecting the calculated phase difference.
  • the optical device according to the exemplary embodiment of the present application is provided in the form of a microscopic optical probe, there may not be enough space to install the above-described detector inside the probe.
  • phase correction unit 220 may pre-store an algorithm for correcting the phase difference.
  • a description of the cause of the above-described phase difference and the phase correction operation performed by the phase correction unit 220 will be described in detail in a related part below.
  • the image restoration unit 230 is a component for restoring an image of an object by reflecting the result of the phase correction performed by the phase correction unit 220 described above.
  • image processing algorithms machine learning algorithms, and the like may be further provided to the image restoration unit 230.
  • the image restoration unit 230 may further provide functions for improving image quality such as noise removal, correction, image segmentation, and image merging in the generated image.
  • the image restoration unit 230 may further provide a function of detecting and displaying a pathological feature in the generated image.
  • the image restoration unit 230 may further automatically diagnose cancer and determine an operation site by detecting a pathological feature in the generated image.
  • the data storage unit 240 may be a memory for storing various types of data, and may include one or more memories.
  • the data storage unit 240 may store algorithms and programs related to various functions provided by the image processing module 200.
  • the data storage unit 240 may store a phase correction algorithm, various image processing algorithms for processing various image processing, and machine learning algorithms.
  • the data storage unit 240 may store image data obtained from the image generating apparatus 1 described above, image data restored by the image restoration unit, and the like.
  • the data storage unit 240 may store algorithms and programs related to various functions performed by the image processing module 200.
  • the data storage unit 240 may store a phase correction algorithm, various image processing algorithms for processing various image processing, and machine learning algorithms.
  • the image processing module 200 may restore a digital image of an object based on a signal transmitted from the image generating device 1, and the image processing module 200 The restored image may be output in real time through the display device 300.
  • the image restored by the image processing module 200 may be transmitted to the image analysis device 2 in real time. Accordingly, the medical technician may perform diagnosis and determination of pathological features such as cancer diagnosis and determination of an operation site based on the restored image.
  • the image processing module 200 is provided with a separate component in the image generating apparatus 1, but functions performed by the image processing module 200 are described above. It may be provided as part of 130.
  • the image processing module 200 may be provided as a separate device or a part of another electronic device.
  • the image processing module 200 may be provided by the control unit 130, and some of the remaining functions may be provided as separate devices.
  • FIG. 6 is a block diagram illustrating an internal configuration of the scanning module 110 according to an exemplary embodiment of the present application.
  • FIG. 7 is a cross-sectional view illustrating an internal configuration of the scanning module 110 according to an exemplary embodiment of the present application.
  • the scanning module 100 may include a driving unit 1101, a scanning unit 1100, and a lens module 1200.
  • the driving unit 1101, the scanning unit 1100, and the lens module 1200 are accommodated in the housing H.
  • the scanning unit 1100 may scan the object O according to a preset scanning pattern by a force applied from the driving unit 1101.
  • the size and shape of the housing H may have various shapes such that at least the scanning unit 1100 can provide a minimum space for driving inside the housing H.
  • the housing (H) may be cylindrical, and the inner diameter (R) of the cylindrical housing (H) considers the maximum driving range for at least one of the first axis and the second axis of the scanning unit 1100 Can be designed by
  • the driving unit 1101 may be an actuator that provides a driving force so that the scanning unit 1100 performs a scanning operation according to a preset scanning pattern.
  • the driving unit 1101 is driven based on any one of a piezoelectric element, an electrostatic, an electromagnetic, an electro thermal, a coil, and a micro motor. It may be an actuator that does.
  • actuators based on piezoelectric elements have advantages of easy packaging for front imaging and high durability compared to actuators based on electromagnetic, electric heat, coil, and micromotors.
  • a piezoelectric element is a device made of a material that generates mechanical energy when electrical energy is applied, or electrical energy when mechanical energy is applied.
  • the piezoelectric material when an electrical signal is applied to a piezoelectric material based on a PZT material, the piezoelectric material may be deformed, and the scanning unit 1100 may vibrate by a force transmitted from the piezoelectric material.
  • the shape of the piezoelectric element can be processed into various shapes such as a triangle, a square, a polygon, a hexahedron, a cylinder, and other three-dimensional shapes.
  • the driving unit 1101 may use a cylindrical piezoelectric element as an actuator.
  • two piezoelectric electrodes facing each other may be driven by a first axis and a second axis, respectively.
  • the driving unit 1101 includes a pair of first actuating units 1101a driven by the first axis and a pair of second actuating units driven by a second axis perpendicular to the first axis It may be composed of (1101b).
  • the first axis may be a vertical axis
  • the second axis may be a horizontal axis orthogonal to the first axis.
  • control unit 130 may apply a driving signal to the first and second driving units 1101, respectively, and the first and second driving units 1101 may apply force generated according to the applied driving signal. It can be transmitted to the scanning unit 1101.
  • the scanning unit 1100 may include an optical fiber 1103, a driving range adjusting means 1110, and a lens module 1200.
  • the optical fiber 1103 may be used as a light transmission path for irradiating the light transmitted from the light irradiation unit 121 to the object.
  • one end or fixed end of the optical fiber 1103 may be coupled to the above-described driving unit 1101.
  • the other end of the optical fiber 1103 may be a free end vibrating by a force applied from the driving part 1101.
  • the driving unit 1101 may apply a force to the actuator position P0 positioned between the fixed end and the free end of the optical fiber 1103.
  • the actuator position Po may be a position at which a force generated as a piezoelectric material is deformed by a driving signal applied to the driving unit 1101 acts.
  • the free end of the optical fiber 1103 may perform a scanning operation according to a preset scanning pattern by the force applied from the driving unit 1101.
  • the optical fiber 1103 may be a cylindrical single fiber, and may be surrounded by a piezoelectric element having a cylindrical structure described above.
  • the optical fiber may vibrate in a first direction by receiving a first force from the first actuating unit 1101a, and may vibrate in a second direction by receiving a second force from the second actuating unit 1101b. have.
  • the free end of the optical fiber 1103 may vibrate by receiving a force according to the deformation of the first actuating part 1101a and the second actuating part 1101b, and the optical fiber 1103 vibrates.
  • Light can be irradiated according to the trajectory to be performed.
  • the aforementioned control unit 130 applies a first driving signal and a second driving signal to the first actuating unit 1101a and the second actuating unit 1101b, respectively, and the first actuation unit 1101a
  • the ting unit 1101a and the second actuating unit 110b transmit a first force according to the application of the first driving signal and a second force according to the application of the second driving signal to the optical fiber, and the free end of the optical fiber Can be driven.
  • the first driving signal may be a first resonance frequency for resonance driving the optical fiber in a first direction
  • the second driving signal may be a second resonance frequency for resonance driving the optical fiber in a second direction
  • this is because, when an object is driven using a resonance frequency, the object has a property to vibrate indefinitely, and a larger swing can be obtained even if the same voltage is applied.
  • the optical fiber 1103 when the free end of the optical fiber 1103 is set to draw a Lissajous pattern, the optical fiber 1103 may be designed to have different resonant frequencies with respect to the first axis and the second axis. .
  • the method of setting the first resonance frequency and the second resonance frequency will be described in detail in the following related sections.
  • the first applied to the driving unit 1101 The resonant frequency and the second resonant frequency may be determined according to the length of the optical fiber 1103 and the stiffness of each of the first and second axes of the optical fiber.
  • one end of the optical fiber 1103 and the driving unit 1101 may be coupled so that the optical fiber 1103 is accurately disposed at the center of the driving unit 1101.
  • the optical fiber is surrounded by the driving unit 1101 having a cylindrical structure
  • at least a part of the optical fiber 1103 may be inserted into the driving unit 1101 to be aligned with the center of the driving unit 1101. have.
  • the optical fiber 1103 is aligned with the center of the cylindrical piezoelectric element, so that the driving unit 1101 is moved by the driving signal applied from the control unit 130 and the axis of the force that the optical fiber 1103 vibrates.
  • the axes can be matched. A method of coupling the optical fiber and the driving unit will be described in detail in the following related section.
  • the driving range adjusting means 1110 may be a structure for adjusting the scanning pattern drawn by the optical fiber 1103 so that the optical fiber 1103 vibrates according to a preset scanning pattern.
  • the optical fiber 1103 in order for the optical fiber 1103 to draw a Lissajou scanning pattern, the optical fiber 1103 must have different driving frequencies for the first axis and the second axis.
  • the resonant frequency fr of the optical fiber 1103 may be determined by Equation 1 below.
  • k is the elastic modulus of the material and m is the mass.
  • the resonant frequency fr of the optical fiber 1103 may vary according to the elastic modulus k of the optical fiber.
  • the elastic modulus k of the optical fiber may be determined according to the stiffness of the optical fiber. For example, in the case of applying a single cylindrical optical fiber 1103, the optical fiber 1103 has the same stiffness for the first axis and the second axis, so that the optical fiber 1103 has the same stiffness for the first axis.
  • the first resonant frequency and the second resonant frequency for the second axis are the same.
  • a structure having a predetermined elasticity may be attached to one of the first axis and the second axis so that the rigidity of the optical fiber 1103 is different with respect to the first axis and the second axis.
  • the structure it is necessary to design the structure so that the first resonant frequency and the second resonant frequency of the optical fiber 1103 have a difference value greater than or equal to a preset range. This is because if the first resonance frequency and the second resonance frequency do not have a difference value greater than or equal to a preset range, the Lissajou scanning pattern drawn by the optical fiber 1103 may be distorted.
  • the driving range adjusting means 1110 is a first axis direction and a second axis in which the optical fiber 1103 vibrates so that the optical fiber 1103 becomes a structure having an asymmetric shape with respect to the first axis and the second axis. It can be attached to any one of the directions.
  • the driving range adjusting means 1110 may be attached to both the first axis direction and the second axis direction so that the optical fiber 1103 becomes a structure having an asymmetric shape with respect to the first axis and the second axis. have.
  • the optical fiber 1103 may vibrate at different driving frequencies in the first direction and the second direction, thereby irradiating a Lisaju pattern meeting a preset criterion.
  • the driving range adjusting means 1110 may include one or more of a mass, a deformable structure, and the like attached to an arbitrary position on the length direction or z-axis of the optical fiber 1103.
  • the driving range in which the optical fiber 1103 vibrates may be adjusted according to the mass attached to the optical fiber 1103, the length, size, shape, attachment position, and attachment angle of the deformable structure.
  • the detailed structure of the driving range adjusting means 1110 will be described in detail through the following related embodiments.
  • the laser beam irradiated from the optical module 120 through the optical fiber 1103 may be directly irradiated to the object through the distal end of the optical fiber.
  • a lens module 1200 for collecting light emitted from the distal end of the optical fiber 1103 may be disposed at the distal end of the optical fiber 1103.
  • an end portion of the optical fiber 1103 may be processed so that light irradiated through the optical fiber 1103 can be collected.
  • the distal end of the optical fiber 1103 may be processed into a spherical shape. Accordingly, the laser beam collected at the distal end of the optical fiber 1103 may be directly irradiated to the object.
  • an end portion of the optical fiber 1103 may be processed, and a lens module 1200 may be further installed at the end portion of the optical fiber 1103 to further improve the NA at the output end.
  • FIG 8 is a diagram illustrating a beam output when an optical fiber 1103 according to another embodiment of the present application is processed into a spherical shape.
  • NA Numerical Aperture
  • the magnification of the lens is fixed, it may be advantageous to use the optical fiber 1103 having a large NA.
  • the end of the optical fiber 1103 may be processed.
  • the end of the optical fiber 1103 may be processed into a conical shape.
  • the side of the optical fiber 1103 may be polished in a conical shape, and the end of the optical fiber 1103 may be polished to have a round shape, thereby processing the end of the optical fiber into a spherical shape.
  • the NA1 of the optical fiber is increased, and accordingly, the NA2 at the output terminal is increased, so that an image having high resolution and no FOA loss can be obtained.
  • FIG 9 and 10 are diagrams for explaining the configuration of the lens module 1200 according to an embodiment of the present application.
  • the scanning unit 1100 may further include a lens module 1200 for collecting light emitted from the distal end of the optical fiber 1103.
  • the lens module 1200 according to the exemplary embodiment of the present application may be designed in consideration of distortion correction for realizing high resolution and processability of the lens module.
  • the lens module 1200 may be designed to have an appropriate size in consideration of miniaturization of the scanning module 110 described above.
  • the lens module 1200 may include at least five or more lenses, and at least one or more of the lenses may be formed as aspherical lenses.
  • the lens module 1200 includes first lenses 1211 and 1221, second lenses 1212 and 1222, and a third lens. It may include (1213, 1223), fourth lenses (1214, 1224), fifth lenses (1215, 1225), sixth lenses (1216, 1226).
  • the resolution and magnification may be optimized according to the ratio of the thickness, thickness and diameter of each lens.
  • the first lenses 1211 and 1221, the second lenses 1212 and 1222, the third lenses 1213 and 1223, the fourth lenses 1214 and 1224, the fifth lenses 1215 and 1225 ) And the sixth lenses 1216 and 1226 may all be aspherical lenses.
  • the first lenses 1211 and 1221 are convergent lenses that collect light entering the optical fiber 1103 and cause the optical axis to be incident in parallel.
  • the first lenses 1211 and 1221 may reduce the loss of light efficiency at the periphery by causing the optical axes to be incident in parallel.
  • the second lenses 1212 and 1222 and the third lenses 1213 and 1223 are lenses for correcting spherical aberration, and the fourth lenses 1214 and 1224 and the fifth lenses 1215 and 1225 perform spherical aberration and chromatic aberration correction. It is a lens for.
  • the fourth lenses 1214 and 1224 and the fifth lenses 1215 and 1225 may be symmetrically bonded to each other in order to increase the chromatic aberration correction effect.
  • sixth lenses 1216 and 1226 may be focusing lenses that finally focus on the object.
  • a separate mounting device 5200 capable of storing the scanning module 110 according to the exemplary embodiment of the present application may be further provided.
  • the mounting device 5200 may be provided with a space for stably accommodating the scanning module 100 therein.
  • a module capable of performing an initial calibration operation may be further provided inside the mounting device 5200 while the scanning module 100 is mounted.
  • the calibration operation performed by the mounting device 5200 will be described in detail in a related part below.
  • the scanning unit 1100 may be designed to irradiate light according to the Lisaju pattern.
  • an additional structure such as a mass and a deformable rod, may be attached to the optical fiber 1103 to perform Lissajou scanning according to a preset condition.
  • an additional structure for adjusting the driving range of the optical fiber 1103 so that the optical fiber 1103 draws a Lisaju figure meeting a preset condition will be described in detail.
  • the overall speed and driving range of the optical fiber scanner may be determined by the length and weight of the optical fiber 1103.
  • the length and weight of the optical fiber 1103 may be first determined so that the optical fiber 1103 draws a scanning pattern that satisfies a preset condition.
  • the scanning unit 1100 may attach a mass (M) to the distal end of the optical fiber 1103.
  • a mass body M having a preset weight may be attached to the distal end of the optical fiber 1103. .
  • the mass body M may have a weight relatively larger than the weight m of the optical fiber 1103.
  • the mass body M is a microstructure in micrometer unit and its mass is very small, the description will be made based on the length ML of the mass body M.
  • the effective mass of the optical fiber 1103 increases, and the driving speed of the scanning unit 1100 decreases. Can be. However, as the effective mass of the optical fiber 1103 increases, the maximum amplitude at which the optical fiber 1103 vibrates may increase.
  • the mass body M may be a microstructure manufactured by a silicon microprocessing process, and the mass body M may be formed into a hexahedron, a sphere, or various other forms capable of processing.
  • the length L of the optical fiber and the length ML of the mass body may be determined according to a target frequency for implementing a high scanning speed.
  • the first resonance frequency in the first axis direction and the second resonance frequency in the second axis direction may both be selected to be 1 kHz or more.
  • the first axis and the second axis are different axes on the xyz axis plane, and when the longitudinal direction of the optical fiber 1103 is the z axis, the first axis is the y axis, and the second axis is the first axis. It may be an orthogonal x-axis.
  • the first axis is a y axis and the second axis is an x axis will be described as an example.
  • FIG. 12 is a graph exemplarily showing a change in resonance frequency according to a length L of an optical fiber 1103 and a length ML of a mass body in the scanning unit 1100 according to an exemplary embodiment of the present application.
  • the length of the mass body M 0.5 mm
  • the scanning amplitude may be further considered during resonance driving.
  • the design conditions of the scanning unit 1100 described above are exemplary, and may be designed in various ways to implement a scanning pattern according to other preset conditions.
  • the maximum amplitude at which the optical fiber 1103 is driven may increase.
  • the FOV of the image obtained according to the vibration of the optical fiber 1103 can be expanded.
  • the mass body M may collide with the lens module 1200 and the lens module 1200 may be damaged. There is this.
  • the lens module 1200 is damaged, a problem may occur that the quality of an image reconstructed by the controller 130 is deteriorated.
  • FIG. 14 is a diagram illustrating an attachment position of a mass body M according to an exemplary embodiment of the present application.
  • an attachment distance for preventing the mass body M from being damaged by colliding with the inner wall of the housing H is defined as a buffer distance.
  • the end of the optical fiber 1103 having a relatively smaller weight than the mass body M and having a small area contacting the inner wall is the housing If it contacts the inner wall of (H), the possibility that the optical fiber 1103 is damaged by collision with the inner wall of the housing (H) may be low.
  • the mass body M is attached to each other by a predetermined distance from the distal end of the optical fiber 1103, so that the mass body M and the housing ( H) It can prevent damage caused by collision of inner wall.
  • the mass body M may be attached between the fixed end and the free end of the optical fiber 1103.
  • the attachment position of the mass body M may be determined in consideration of one or more of elements for implementing a scanning pattern according to preset conditions, such as, for example, a resonance frequency, a scanning speed, and an adjustment of a driving range of the optical fiber 1103.
  • the mass body (M) be attached adjacent to the free end side of the optical fiber 1103 based on a 1/2 point of the entire length (L) of the optical fiber in order to improve the scanning speed and expand the FOV. I can.
  • the mass body M in order to improve the scanning speed, expand the FOV, and minimize damage due to collision of the mass body M with the inner wall of the housing H, the mass body M is the whole of the optical fiber. It may be attached between the point 1/2 of the length (L) and the shortest part of the optical fiber.
  • the collision avoidance distance BD may be defined as in Equation 2 below.
  • the collision avoidance distance BD may be determined by further considering the length ML of the mass body M.
  • the collision avoidance distance BD is at least equal to or greater than the length ML of the mass body M, it is possible to prevent the mass body M from colliding with the inner wall of the housing H.
  • the collision avoidance distance BD may be set based on the maximum driving range of the optical fiber 1103 and the mass M and the inner diameter W of the housing H. This is to reduce the size of the housing (H) and to prevent damage to the optical fiber 1103 and the mass body (M).
  • the maximum driving range in which the optical fiber 1103 can vibrate is based on the center point of the inner diameter of the housing H. Assuming that D1, the maximum driving range in which the mass body M can vibrate is D2 based on the center point of the inner diameter of the housing H,
  • D2 may be the highest point when the mass body M moves to the maximum driving range inside the housing H so that the mass body M does not collide with the inner wall of the housing H.
  • the collision avoidance distance (BD) may be determined in consideration of all the length ML of the mass body, the maximum vibrating range of the optical fiber and the mass body with respect to the first axis, and the inner diameter of the housing (H). .
  • the scanning module 110 minimizes damage to each component packaged in the scanning module 110 while minimizing the packaging of the scanning module 110, thereby reducing product performance and It is possible to provide an optical device with improved durability.
  • a driving range adjusting means 1110 may be further attached to the optical fiber 1103 according to the exemplary embodiment of the present application to perform Lisaju scanning according to a preset condition.
  • the resonance frequency of the optical fiber 1103 must have different values for the first axis and the second axis.
  • the resonance frequencies for the first axis and the second axis must have a difference of more than a preset range.
  • the resonance frequency for the first axis and the second axis does not differ by more than a preset range, the Lisaju pattern irradiated from the optical fiber 1103 may be distorted.
  • a first resonant frequency (fy) with respect to the first axis of the optical fiber 1103 and a second resonant frequency (fx) with respect to the second axis are at least of the resonant frequency (fr) of the optical fiber 1103 It needs to be more than FWHM (Full Width Half Maximum).
  • the first resonant frequency (fy) and the second resonant frequency (fx) of the optical fiber 1103 are, the resonant frequency (fr) of the optical fiber 1103 It may be desirable to be separated by more than the FW (Full Width) of.
  • the difference between the first resonant frequency fy and the second resonant wave number fx may be 200 Hz, which is the FW of the resonant wave number fr. .
  • the optical fiber 1103 can be connected to each other with respect to the first and second axes. It can be designed to have different stiffness (k).
  • the optical fiber 1103 is asymmetric with respect to the first axis and the second axis. You can make it a structure. This is because the resonant frequencies of the optical fiber 1103 with respect to the first axis and the second axis may vary according to the stiffness of each of the first axis and the second axis of the optical fiber.
  • the optical fiber 1103 may be desirable to design the optical fiber 1103 to have a rigidity ratio (ky/kx) of the first axis and the second axis not exceeding 1. Because the driving range (displacement) of the scanner varies depending on the rigidity of each axis, when the ratio of the rigidity to each axis increases, the FOV of the image reconstructed by the controller 130 may not be properly secured.
  • 16 is a diagram for explaining a structure of a driving range adjusting means 1110 according to an exemplary embodiment of the present application.
  • the driving range adjusting means 1110 may include a first connector 1111, a deformable rod 1112, and a second connector 1113.
  • the driving range adjusting means 1110 allows the optical fiber 1103 to have a resonance frequency difference by more than a preset range with respect to the first axis and the second axis. It may be designed to be an asymmetric structure with respect to the second axis. Accordingly, the optical fiber 1103 may irradiate a Lisaju pattern that is not coupled. The coupling phenomenon of the Lissajou pattern irradiated by the optical fiber 1103 will be described in detail in the following related section.
  • the controller 130 is described on the assumption that the first driving frequency is applied to the first actuating unit 1101a and the second driving frequency is applied to the second actuating unit 1101b. do.
  • the controller 130 may apply the first driving frequency and the second driving frequency to the first actuating unit 1101a and the second actuating unit 1101b, and the first actuating unit 1101a and the second actuating unit 1101b. Mechanical deformation may occur in the ting portion 1101a and the second actuating portion 1101b.
  • the force generated by the mechanical deformation of the first actuating unit 1101a and the second actuating unit 1102b may be transmitted to the first and second axes of the optical fiber 1103, respectively, and the The optical fiber 1103 may vibrate in a first axis and a second axis by a force transmitted from the first actuating unit 1101a and the second actuating unit 1101b.
  • first driving frequency applied to the first actuating unit 1101a may cause vibration on the first axis of the optical fiber 1103, and a second driving frequency applied to the second actuating unit 1101b
  • the driving frequency may cause vibration about the second axis of the optical fiber 1103.
  • a deformable rod 1112 is attached to at least one of the first and second axes of the optical fiber 1103 to change the rigidity of the optical fiber 1103 with respect to at least one of the first and second axes. It may be an elastic structure.
  • the optical fiber 1103 may be resonantly driven according to a first force applied from the first actuating unit 1101a and a second force applied from the second actuating unit 1101b, and the deformable rod ( 1112 may change the rigidity of at least one of the first axis and the second axis of the optical fiber 1103 when the optical fiber 1103 is driven in resonance.
  • the optical fiber 1103 may have a first rigidity
  • the deformable rod 1112 may have a second rigidity.
  • the second stiffness may be equal to or greater than the first stiffness.
  • the deformable rod 1112 may be attached on the first axis of the optical fiber 1103 to amplify the vibration of the optical fiber 1103 in the first axis direction.
  • the optical fiber 1103 may be an asymmetric structure with respect to the first axis and the second axis. Accordingly, a difference in resonant frequencies with respect to the first and second axes of the optical fiber 1103 occurs.
  • the deformable rod 1112 may be formed of a material having a predetermined elastic force in order to amplify the vibration generated by the first or second axis of the optical fiber 1103.
  • the shape of the deformable rod 1112 may vary.
  • FIG. 16 it may have a rectangular bar or wire shape.
  • the deformable rod 1112 may be disposed adjacent to the optical fiber 1103 in the z-axis direction, which is the longitudinal direction of the optical fiber 1103, and may be spaced apart from the optical fiber 1103 by a predetermined distance. .
  • the deformable rod 1112 may have a first end and a second end.
  • a first end of the deformable rod 1112 is fixed to a first rod position P1 on the optical fiber 1103, and the second end is fixed on the optical fiber 1103. It may be fixed to the second rod position P2.
  • the first rod position P1 and the second rod position P2 are between the actuator position P0 and the free end of the optical fiber 1103.
  • the actuator position P0 may be a position where a force for vibrating the optical fiber is transmitted according to a driving signal applied to the first actuating unit 1101a and the second actuating unit 1102b.
  • the actuator position P0 may be located between the fixed end and the free end of the optical fiber 1101.
  • the first actuating part 1101a may be configured to apply a first force to the actuator position P0, and the free end of the optical fiber 1103 may be driven to resonantly drive in the first direction.
  • the second actuating part 1101b may be configured to apply a second force to the actuator position P0, and the free end of the optical fiber 1103 may be driven to resonantly drive in the first direction. .
  • the deformable rod 1112 has the first axis and the second axis so that the optical fiber 1103 has different resonance frequencies with respect to the first axis and the second axis and simultaneously irradiates a Lisaju pattern according to a preset condition.
  • One or more may be installed so that the resonance frequency for the shaft is separated by more than a predetermined range.
  • the first connector 1111 and the second connector 1113 may be a fixer or a microstructure for supporting the above-described deformable rod 1112.
  • the first connector 1111 and the second connector 1113 may be a silicon microstructure, and may be manufactured by a silicon wafer microprocessing.
  • the first connector 1111 and the second connector 1113 are on the optical fiber 1103 while the deformable rod 1112 is spaced apart from the optical fiber 1103 by a predetermined distance. It may be an adhesive to fix it on.
  • first connector 1111 and the deformable rod 1112 may be attached on the z-axis of the optical fiber 1103.
  • the deformable rod 1112 may be located between the first connector 1111 and the deformable rod 1112, and the first end and the second end of the deformable rod 1112 are the first It may be connected by a connector 1111 and the deformable rod 1112.
  • the first connector 1111 and the deformable rod 1112 may be a fixer fixed to the optical fiber 1103.
  • a predetermined groove may be formed in the first connector 1111 and the deformable rod 1112 so as to be stably fixed on the optical fiber 1103.
  • the shapes of the first connector 1111 and the second connector 1113 may be designed in various shapes within a range capable of supporting the deformable rod 1112 by being fixed to the optical fiber 1103. .
  • the deformable rod 1112 and the first connector 1111 and the second connector 1113 supporting the first and second ends of the deformable rod 1112 are provided with vibration of the optical fiber 1103 Can move together according to.
  • the deformable rod 1112 is The vibration in the direction of the first axis of 1103) may be amplified.
  • the deformable rod 1112 is The vibration in the second axis direction of (1103) may be amplified.
  • the optical fiber 1103 may have different resonance frequencies with respect to the first axis and the second axis.
  • some of the force applied in the first axis direction may be transmitted in the second axis direction of the optical fiber 1103, so that vibration in the second axis direction may also be amplified.
  • some of the force applied in the second axis direction may be transmitted to the first axis direction of the optical fiber 1103, so that vibrations in the first axis direction may also be amplified.
  • the scanning unit 1100 by attaching a deformable rod 1102 to any one of the first and second axes driven by the optical fiber 1103
  • the optical fiber 1103 may have different resonance frequencies with respect to the first axis and the second axis.
  • 17 is a view for explaining the attachment position of a deformable rod for designing such that the resonant frequencies of the first axis and the second axis of the optical fiber 1103 differ by more than a preset range in an exemplary embodiment of the present application.
  • the difference between the resonant frequencies of the optical fiber 1103 with respect to the first axis and the second axis may vary according to the attachment position of the deformable rod 1112 described above, so the installation of the deformable rod 1112 It is necessary to adjust the position L1 and the length L2.
  • the installation position (L1) of the deformable rod 1112 is based on the distance from the fixed end of the optical fiber 1103 to a point 1/2 of the total length (L2) of the deformable rod 1102 Can be determined.
  • the deformable rod 1112 may be disposed side by side with the optical fiber 1103 separated by a predetermined distance, and separated by L1 from one end of the optical fiber 1103. Can be installed on site.
  • the deformable rod 1112 may be installed at a distance L3 from the mass body M installed at the distal end of the optical fiber 1103 by a predetermined distance L3.
  • first connector 1111 and the second connector 1113 may be designed to have a relatively very small mass compared to the mass body M.
  • the first connector 1111 and the second connector 1113 may be designed to have a mass equal to or greater than that of the mass body M.
  • FIG. 18 is a diagram illustrating a structure of a driving range adjusting means 1110 according to another embodiment of the present application.
  • a driving range adjustment means 1110 may include a first connector 1111, a deformable rod 1112, and a second connector 1113, and FIG. 17
  • the mass body M described above may simultaneously perform the function of the second connector 1113.
  • the deformable rod 1112 may be supported by the first connector 1111 and the mass body M.
  • the installation position L1 of the deformable rod 1112 and the length L2 of the deformable rod 1112 may be different from the case in which a separate mass M is installed.
  • the mass body M needs to be installed at an appropriate position to perform both a function for adjusting the driving speed of the scanning unit 1100 and as an auxiliary member for supporting the deformable rod 1112. .
  • the deformable rod 1112 may be installed at a location L11 spaced apart from one end of the optical fiber 1103 by a predetermined distance. At this time, as described above with reference to FIG. 14, the collision avoidance distance with the inner wall of the housing may be further considered.
  • the deformable rod 1112 Distortion may still occur in the scanning pattern irradiated by the optical fiber 1103 depending on the attachment direction.
  • cross coupling a phenomenon in which a force transmitted in one axis direction affects the other axis and is amplified.
  • FIG. 19 is a diagram exemplarily illustrating an eccentricity phenomenon according to an embodiment of the present application.
  • control unit 130 applies the first driving signal to the first actuating unit 1101a, some of the force that should be transmitted only to the first axis of the optical fiber 1103 is also transmitted to the second axis. As a result, eccentricity may be generated in the second axis by the transmitted force.
  • a mechanical coupling or a coupled-lissajous pattern may be generated in the second axis direction.
  • the control unit 130 applies the second driving signal to the second actuating unit 1101b, some of the force to be transmitted only to the second axis of the optical fiber 1103 is transferred to the first axis. Also transmitted, the eccentricity may be generated in the first axis as much as the transmitted force.
  • a mechanical coupling or a coupled-lissajous pattern may be generated in the first direction.
  • a mechanical coupling or a coupled Lisaju pattern is defined as a'coupling error'.
  • the causes of the coupling error may be various.
  • the force axis (x) of the optical fiber 1103 is Axis, y-axis) and the resonant driving shafts (x', y') in which the optical fiber 1103 is actually driven do not coincide.
  • the driving unit 1101 is not a perfect circle, the centers of the inner and outer diameters do not coincide, so that the force axis (x-axis, y-axis) of the optical fiber 1103 and the optical fiber 1103 actually vibrate. This may be because it is impossible to drive to match the driving shaft (x' axis, y'axis).
  • the force axes (x-axis, y-axis) transmitted to the optical fiber 1103 and the resonance driving shaft of the optical fiber 1103 can be adjusted to match. This is because the resonant drive shaft of the optical fiber 1103 may vary depending on the attachment position and/or direction of the deformable rod 1112.
  • a predetermined error may occur when the image restored based on the scanning pattern irradiated from the optical fiber 1103 has a quality higher than a preset level. Can be allowed.
  • the deformable rod 1112 is supported by the first connector 1111 and the second connector 1113, and the optical fiber 1103 has different resonance frequencies with respect to the first and second axes.
  • the rigidity of at least one of the first axis and the second axis of the optical fiber 1103 may be changed so as to be performed.
  • the first end of the deformable rod 1112 may be fixed in the first rod position on the optical fiber 1103, and the second end may be fixed in the second rod position on the optical fiber 1103. have.
  • the deformable rod 1112 may perform a function of amplifying the vibration of the first axis or the second axis while being supported by the first connector 1111 and the second connector 1113.
  • compression (C) and expansion (E) of the deformable rod 1112 may occur in both the first axis direction and the second axis direction.
  • compression (C) and expansion (E) of the deformable rod 1112 may occur only in the first direction.
  • 21 and 22 are cross-sectional views for explaining an attachment position of a deformable rod according to embodiments of the present application.
  • the attachment position of the deformable rod in the longitudinal direction of the optical fiber 1103 or in a cross section perpendicular to the Z direction is from the second end of the deformable rod 1112 to the second rod on the second optical fiber.
  • the virtual line A2 connected to the position may be determined to coincide with the first axis A1 of the optical fiber. This is because the resonant drive axis in which the optical fiber 1103 actually drives is determined by a virtual line A2 connected from the second end of the deformable rod 1112 to the second rod position on the second optical fiber. to be.
  • the attachment position of the deformable rod 1112 is shown in FIG. 23 when the axis of force (first axis) of the optical fiber 1103 and the resonant drive shaft actually driven by the optical fiber 1103 are attached to match.
  • the resonant frequencies of the first axis and the second axis of the optical fiber 1103 may be separated by more than a preset range.
  • the control unit 130 applies the first driving signal to the first actuating unit 1101a
  • the vibration of the optical fiber 1103 induced by is amplified not only in the first axis direction but also in the second axis direction, and a predetermined coupling error (r) phenomenon may occur as shown in FIG. 19(b).
  • the control unit 130 applies a second driving signal to the second actuating unit 1101b
  • the second force applied to the actuator position on the optical fiber 1103 from the second actuating unit 1101b The vibration of the optical fiber 1103 induced by the optical fiber 1103 is amplified not only in the second axis direction but also in the second axis direction, so that a predetermined coupling error (r) phenomenon may occur as shown in FIG. 19(a). .
  • an uncoupled Lissajou pattern may be generated.
  • the attachment position of the deformable rod in the longitudinal direction of the optical fiber 1103 or in a cross-section perpendicular to the Z direction is from the second end of the deformable rod 1112 to the second optical fiber. It may be determined based on the angle ⁇ between the virtual line A2 connected to the load position and the first direction A1.
  • the attachment position P1 of the deformable rod 1112 may be determined to be away from the optical fiber 1103 on the virtual line A2.
  • the deformable rod 1112 may be disposed to be spaced apart from the optical fiber 1103 by a predetermined distance.
  • the deformable rod 1112 may be installed substantially parallel to the optical fiber 1103.
  • the deformable rod 1112 may be disposed in parallel with the optical fiber 1103.
  • the deformable rod 1112 may be disposed to at least partially overlap the optical fiber 1103.
  • a virtual line A2 and a first axis direction A1 connected from the attachment position P1 of the deformable rod 1112 to the second rod position on the optical fiber The inter angle ⁇ may be within a total range of 10 degrees +a degrees and -b degrees based on the first axis direction A1. In this case, a and b may have different values.
  • the angle ⁇ between the virtual line A2 and the first axis direction A1 connected from the attachment position P1 of the deformable rod 1112 to the second rod position on the optical fiber May be within a total range of 5 degrees +a degrees and -b degrees based on the first axis direction A1.
  • a and b may have different values.
  • the attachment angle range ⁇ may be a value calculated according to a preset reference.
  • the preset criterion may reflect an allowable coupling error r so that the resolution of an image restored based on the scanning pattern irradiated by the optical fiber 1103 can be maintained at a predetermined level or higher.
  • the attachment angle range ⁇ is the first actuating part 1101a to apply the first driving signal to the actuator position of the optical fiber 1103 from the first actuating part 1101a. 1 It may be calculated by considering the efficiency (a) of the force generated in the second axis direction of the optical fiber 1103 and the efficiency (b) of the driving range according to the force.
  • the second axis (x axis) is also predetermined. As the force of is transmitted, vibration may be amplified even in the second axis direction.
  • Equation 3 represents the force (Y) transmitted to the y-axis
  • Equation 4 represents the force (X') transmitted to the x-axis.
  • the driving range (r) in the x-axis direction is,
  • FIG. 25 is a state in which the deformable rods 1112 are installed side by side on the optical fiber 1103 in the scanning module 110 according to an embodiment of the present application, and the resonance frequencies of the x-axis and the y-axis are separated by A. It is a graph for illustrating a driving range in the x-axis direction induced by a force transmitted from the first actuating unit 11011 by way of example.
  • the driving range (r) in the x-axis direction is
  • the driving range r in the second axis (x-axis) direction may be allowed within a range of at least 1/2 of the preset system resolution.
  • the resolution of the reconstructed image is set at a preset level since it is possible to distinguish between pixels. Because you can keep it.
  • the attachment angle range of the deformable rod 1112 in which the driving range r in the second axis (x-axis) direction is within 1/2 of the preset system resolution ( ) Is,
  • the attachment angle range of the deformable rod 1112 is the resolution of the system, the total number of pixels, the maximum driving range of the first axis or the second axis, and the efficiency of the force transmitted to the second axis or the first axis. It may be calculated by considering at least one of them.
  • FIG. 26 is a graph for explaining the attachment angle of the deformable rod 1112 according to the driving range efficiency (b) in the second axis (x-axis) direction when Fx and Fy are the same.
  • the attachment angle that allows a predetermined coupling error is at most 10 degrees. It may be within the range.
  • the attachment position or attachment angle of the deformable rod 1112 is induced in the second axis direction when the driving signal in the first axis direction is applied to the first actuating unit 1101a. It may be determined that the driving range of the optical fiber 1103 is less than 10% of the maximum driving range induced in the first axis direction.
  • the attachment angle range of the deformable rod 1112 may be within 4 degrees.
  • a coupling error r may be allowed within a range capable of maintaining the quality of a restored image above a certain level.
  • the deformable rod 1102 is properly attached to the optical fiber 1103 within the above-described allowable coupling error (r), so that the optical fiber 1103 can be applied to the first actuator.
  • vibration in the other axial direction may be limited.
  • 27 to 30 are views showing frequency characteristics according to the attachment direction of the above-described deformable rod 1112.
  • At least one deformable rod 1112 is installed spaced apart from the optical fiber 1103 by a predetermined distance, and the resonant frequencies of the first and second axes of the optical fiber are sufficiently separated. It is assumed that the possible rod 112 is attached within the above-described attachment angle range.
  • the elastic modulus of the axis to which the deformable rod 1112 is attached (k) The value can be increased. This is because, assuming that the influence of the k value of the deformable rod 1112 is greater than that of the mass M, the stiffness of the optical fiber 1103 of the shaft to which the deformable rod 1112 is attached increases.
  • the driving frequency of the shaft to which the deformable rod 1112 is attached may have a larger value.
  • the maximum driving range of the x-axis and y-axis in which the optical fiber 1103 vibrates may vary according to a difference in driving frequency between the x-axis and the y-axis. That is, the amplitude value at which the optical fiber 1103 vibrates is different.
  • the aspect ratio of the x-axis and y-axis of the scanning pattern irradiated by the optical fiber 1103 may be different.
  • the aspect ratio of the x-axis and y-axis images output from the image generating device 1 may not be 1:1.
  • the output aspect ratio may be calculated as follows.
  • kx is the spring constant for the x-axis
  • ky is the spring constant for the y-axis
  • m is the mass
  • the resonant frequency of the x-axis is 1100 Hz
  • the resonance frequency of the y-axis is 1300 Hz
  • the optical fiber 1103 The aspect ratio (FOVy: FOVx) of the scanning pattern irradiated by is approximated to 1: 1.4.
  • the attachment direction of the deformable rod 1112 may be determined in consideration of a preset aspect ratio.
  • controller 130 may adjust an aspect ratio of an image output through the display device through voltage control.
  • the controller 130 may adjust the aspect ratio of the scanning pattern irradiated by the optical fiber 1103 by adjusting the voltage applied to the first actuating unit 1101a and the second actuating unit 1101b.
  • the control unit 130 has a voltage greater than that of the x-axis on the y-axis.
  • control unit 130 is the same for the first actuating unit 1101a and the second actuating unit (y-axis) so that the output image has different aspect ratios for the x-axis and y-axis. Voltage can be applied.
  • the controller 130 may correct the aspect ratio of the output image by applying a first voltage to the first actuating unit 1101a and a second voltage to the second actuating unit 1101b. have.
  • the controller 130 may correct the image based on the aspect ratio information input from the user.
  • FIG. 30 is a flowchart illustrating an aspect ratio correction method according to an exemplary embodiment of the present application.
  • the step of receiving aspect ratio information from a user may include determining (S12), generating an image corresponding to the aspect ratio (S13), and the like.
  • a deformable rod 1112 is provided in the optical fiber 1103 so that the force transmitted to one axis of the optical fiber 130 does not cause maximization of vibration of the other axis. It is attached in the y-axis direction of, and the resonant frequency of the x-axis is set to 1100 Hz, and the resonance frequency of the y-axis is set to 1300 Hz.
  • the controller 130 may receive aspect ratio information from a user (S11).
  • the user may input a request corresponding to the aspect ratio change through the above-described input unit in order to observe an image according to a desired aspect ratio.
  • a plurality of modes may be preset to provide a converted image to an image corresponding to a predetermined ratio.
  • the controller 130 may obtain aspect ratio information received through the input unit, and may further check preset system resolution information.
  • controller 130 may determine a voltage to be applied to the first axis and the second axis based on the aspect ratio information received from the user (S12).
  • the controller 130 For example, if the aspect ratio information received from the user in step S11 is a:b, the controller 130 generates an image corresponding to the aspect ratio information by applying a first voltage to the x-axis and a second voltage to the y-axis. I can.
  • the controller 130 may control the y-axis to apply a larger voltage than the x-axis.
  • controller 130 may generate an image corresponding to the aspect ratio (S13).
  • the controller 130 may convert and provide an image corresponding to an aspect ratio desired by the user based on the aspect ratio information received in step S11 and the voltage information determined in step S12.
  • the attachment position of the deformable rod 1102 additionally attached to the optical fiber 1103 may be determined according to a preset image aspect ratio.
  • control unit 130 may adjust the first driving signal for the first axis and the second driving signal for the second axis to be applied to the driving unit 1101, thereby correcting and providing an image having a desired ratio. have.
  • FIGS. 32 to 34 are views for explaining a coupling structure for accommodating each component in a housing in the scanning module 110 according to the exemplary embodiments of the present application.
  • the scanning module 110 may be provided in the form of a handheld optical fiber probe.
  • various types of fixing elements may be provided for compact and robust packaging of the components inside the probe.
  • the driving unit 1101 is a piezoelectric element based on a PZT material, and a case where a piezoelectric element having a cylindrical structure is applied will be described as an example.
  • a first fixing element 1104 for aligning the center of the driving unit 1101 and the optical fiber 1103 may be provided.
  • the first fixing element 1104 may have a cylindrical ring shape.
  • the first fixing element 1104 may be made of a non-conductive material because four electrodes of the drive 1101 must be insulated from each other.
  • the outer diameter OD1 of the first fixing element 1104 may be designed to be larger or smaller by a predetermined size than the inner diameter ID1 of the driving unit 1101.
  • an inner diameter ID1 of the driving part 1101 may be about 0.9 mm
  • an outer diameter OD1 of the first fixing element 1107 may be about 0.904 mm.
  • the inner diameter (ID) of the first fixing element (1104) is designed to be larger than the outer diameter (OD1) of the optical fiber (1103) by a predetermined size to facilitate assembly of the optical fiber (1103) and the driving unit (1101). I can do it.
  • the optical fiber 1103 may pass through the first fixing element 1104 so that the center of the optical fiber 1103 may be aligned to be located at the center of the driving part 1101.
  • a second fixing element 1107 for supporting one end of the housing H may be further provided.
  • the outer diameter OD2 of the second fixing element 1107 may be designed in consideration of the inner diameter of the housing H tube, and the inner diameter ID2 of the second fixing element 1107 is the driving part 1101 It can be designed in consideration of the outer diameter of ).
  • a third fixing element 1105 for fixing one end of the optical fiber 1103 to the PZT element may be provided.
  • the center of the PZT element 1103 and the optical fiber 1101 may be aligned by the third fixing element 1105.
  • the inner diameter ID3 of the third fixing element 1105 may be designed in consideration of the outer diameter OD3 of the optical fiber 1103.
  • the outer diameter OD3 of the third fixing element 1105 may be designed in consideration of the inner diameter D3 of the driving part 1101.
  • the third fixing element 1105 may be inserted from the front end of the optical fiber passing through the first fixing element 1104 and the driving unit 1101 to the inside of the driving unit 1101.
  • the optical fiber 1103 and the driving unit 1101 may be aligned by the third fixing element 1105 to maintain coupling.
  • an adhesive may be used so that the optical fiber 1103 maintains a bonding force with the driving unit 1101.
  • uv or heat curable epoxy can be used as an adhesive.
  • one or more modules for maintaining a constant temperature inside the probe may be disposed inside the housing of the optical fiber probe.
  • At least one temperature sensor and temperature control means may be disposed inside the scanning module 110 according to another exemplary embodiment of the present application.
  • a difference in driving of the actual optical fiber may occur depending on the usage environment, such as the temperature inside the operation room and/or the internal body temperature.
  • the resonant frequency of the optical fiber may vary.
  • the temperature control means may include at least one of a heater and a cooler.
  • a heater 1121 and a temperature sensor 1123 may be disposed inside the scanning module 110 according to another embodiment of the present application.
  • a heater 1121 may be installed along the inner wall of the housing H.
  • At least one temperature sensor 1123 may be disposed inside the housing H.
  • the controller 130 may be set to control the operation of the heater 1121 when it is determined that the temperature detected by the temperature sensor 1123 does not meet a preset standard.
  • the inside of the scanning module 110 is heated for a predetermined time by the heater 1121. It is possible to control the operation of the heater 1121 to be able to.
  • the controller 130 may turn off the heater 1121 so as not to operate.
  • a packaging method using an insulating material may be used to maintain a constant temperature condition inside the optical fiber probe.
  • the driving condition of the scanning module 110 may be kept constant.
  • the scanning module 110 by installing the magnet M inside the housing H, the actual movement of the optical fiber 1103 may be recognized.
  • the mass body M attached to the distal end of the optical fiber 1103 is a magnet
  • the magnet can confirm the actual moving position of the optical fiber 1103 performing the Lissajou scanning by the force transmitted from the driving unit 1101.
  • a phase difference generated in the process of transmitting a driving signal applied to the scanning module 110 from the control unit 130 to the scanning module 110 It may be possible to directly calculate.
  • At least a first magnet MG1 and a second magnet MG2 may be disposed inside the scanning module 110 according to another embodiment of the present application.
  • the first magnet MG1 may be a mass M attached to the end of the optical fiber 1103.
  • the second magnet MG2 may be configured to detect positional information on the first axis and the second axis of the optical fiber 1103.
  • a magnet for detecting position information on each of the first and second axes of the optical fiber 1103 may be separately disposed.
  • the image generating device irradiates light and generates an image using the returned light. For example, after light is output from the light irradiation unit 121, light is irradiated to the object O through the scanning module 110, and light reflected, scattered, refracted, and diffracted from the object O is imaged. Returning to the device, it may be obtained from the light receiving unit 123. In this case, the controller 130 may acquire light-receiving information indicating information on the received light.
  • the controller 130 may control the light irradiation unit 121 to output light, and the driving unit 1101 of the scanning module 110 to irradiate light to the object O according to a predetermined pattern. ) Can be controlled.
  • the signal for controlling the driver 1101 may include an AC signal, and the AC signal may be a signal having a frequency component and a phase component to be applied to the driver 1101.
  • the signal for controlling the driving unit 1101 may have at least one signal to be applied to the scanning module 110 in each orthogonal axis direction.
  • the control unit 130 may operate the driving unit 1101 by applying a driving signal to the driving unit 1101.
  • the driving unit 1101 may output a signal for controlling the scanning unit 1100 (hereinafter, a scanning unit driving signal), and may drive the scanning unit 1100 according to the output of the driving signal of the scanning unit 1100.
  • the driven scanning unit 1100 may irradiate light based on an output signal (hereinafter, referred to as an output signal of the scanning unit) for irradiating light in accordance with a predetermined pattern.
  • the driving signal, the scanning unit driving signal, and the scanning unit output signal may be electrical signals, but are not limited thereto, and may include a signal indicating motion according to an input of a signal.
  • a driving signal is input to the driving unit 1101, and driving or movement of the driving unit 1101 according to the driving signal may be expressed as a scanning unit driving signal.
  • the scanning unit driving signal is input to the scanning unit 1100, and driving or movement of the scanning unit 1100 according to the scanning unit driving signal may be expressed as a scanning unit output signal.
  • the driving signal, the scanning unit driving signal, and the scanning unit output signal may include signals based on various waveforms (eg, sin function waveform).
  • the driving signal, the scanning unit driving signal, and the scanning unit output signal may be the same signal, but the driving signal, the scanning unit driving signal, and the scanning unit output signal may be signals having different phases.
  • 38 is a diagram illustrating a comparison between a waveform of a signal before a phase is delayed and a waveform of a signal after a phase is delayed.
  • the x-axis represents time and the y-axis represents amplitude.
  • the signal 5000 before the phase delay and the signal 5001 after the phase delay may both represent signals having the same amplitude and the same waveform.
  • the present invention is not limited thereto, and the amplitude or waveform of the signal before phase delay 5000 and the signal after phase delay 5001 may be different from each other, or even within the signal before phase delay 5000 or after the phase delay signal 5001 Depending on the case, the same amplitude or waveform may not be displayed continuously.
  • the post-phase delay signal 5001 represents a signal whose phase is delayed compared to the pre-phase delay signal 5000, and the phases of the pre-phase delay signal 5000 and the post-phase delay signal 5001 may be different from each other.
  • the signal 5001 after the phase delay has a constant phase difference compared to the signal 5000 before the phase delay at each time point, but is not limited thereto, and the signal 5000 and the pre-phase delay signal 5000 at each time point After the phase delay, the delayed phase degree of the signal 5001 may be different.
  • the signal before phase delay 5000 and the signal after phase delay 5001 may be applied to both the aforementioned driving signal, scanning unit driving signal, or scanning unit output signal.
  • the driving signal and the scanning unit driving signal may have different phases.
  • the phase of the driving signal and the phase of the scanning unit driving signal may differ from each other as energy including heat or sound is emitted from the driving unit 1101. have.
  • the driving unit 1101 is driven by receiving a driving signal, as the structure (or shape) of the driving unit 1101 is deformed, the phase of the driving signal and the phase of the scanning unit driving signal may be different from each other.
  • the change in the structure of the driving unit 1101 may mean that the structure of the driving unit 1101 is changed as the driving unit 1101 is driven by inputting a driving signal.
  • the change in the structure of the driving unit 1101 may include the expansion or contraction of the driving unit 1101 as the driving unit 1101 is driven.
  • the present invention is not limited thereto, and the structure of the driving unit 1101 may be changed due to external causes other than inputting a driving signal.
  • the scanning unit driving signal and the scanning unit output signal may have different phases.
  • the phase of the scanning unit driving signal and the scanning unit output signal May have different phases.
  • the scanning unit 1100 is driven by receiving a driving signal of the scanning unit, as the structure (or shape) of the scanning unit 1100 is deformed, the phase of the driving signal of the scanning unit and the phase of the output signal of the scanning unit are They can be different.
  • the change in the structure of the scanning unit 1100 may mean that the structure of the scanning unit 1100 is changed as the scanning unit 1100 is driven by inputting a scanning unit driving signal.
  • the change in the structure of the scanning unit 1100 may include extending or contracting the scanning unit 1100 as the scanning unit 1100 is driven.
  • the present invention is not limited thereto, and the structure of the scanning unit 1100 may be changed for reasons according to external causes other than inputting the driving signal of the scanning unit 1100.
  • a preset reference image may exist, and the reference image may be used to determine the phase delay.
  • the preset reference image may be a circular pattern, but is not limited thereto. Accordingly, it is possible to determine the degree of phase delay by comparing the reference image and the image acquired by the controller 130.
  • (a) shows a low-resolution image in which the phase is delayed
  • (b) shows a phase correction image obtained by correcting the delayed phase, and shows a high-resolution image.
  • the controller 130 may correct the phase of the signal after the phase delay so that an image as shown in FIG. 39 (b) may be obtained instead of the image as shown in FIG. 39 (a).
  • the controller 130 may obtain a phase correction image in which the delayed phase is corrected by using the phase adjusted through the input unit 140.
  • the input unit 140 may adjust a frequency component of a signal for controlling the driving unit 1101 from the control unit 130, or a phase component, or both a frequency component and a phase component. , Is not limited thereto.
  • the phase of the driving signal may be adjusted through the input unit 140, and as the phase of the driving signal is adjusted, the control unit 130 adjusts the phase component instead of the low-resolution image by the signal after the phase delay. It is possible to obtain a corrected high-resolution image.
  • the controller 130 may automatically adjust the phase to obtain a phase correction image in which the delayed phase is corrected.
  • the controller 130 may automatically correct the phase component of the driving signal.
  • the phase component may be corrected using an algorithm. Phase correction using the algorithm will be described below.
  • phase value that must be adjusted by the controller 130 may be small. Accordingly, the time to perform the phase correction is reduced, and the phase can be more accurately corrected.
  • the range of the phase to be adjusted by the input unit 140 may be small.
  • the phase is corrected by using an algorithm, it is possible to reduce the amount of calculation required up to the corrected phase value through the initial phase correction.
  • the initial phase correction may be defined as representing a phase correction method other than the phase correction using the following algorithm.
  • the initial phase correction may include phase correction using the mounting device 5200 to be described below, phase correction using a cut-off filter, and phase correction using the fine patterning forming unit 5100.
  • various phase correction methods may be included in the initial phase correction.
  • the phase when scanning is performed on the object O, after performing initial phase correction, the phase may be corrected through the input unit 140 or the phase may be corrected using the following algorithm.
  • initial phase correction may be performed, and thereafter, phase correction using the algorithm may be performed again.
  • present invention is not limited thereto, and initial phase correction and phase correction using an algorithm may be performed simultaneously.
  • an image may be obtained by performing only initial phase correction without performing phase correction using an algorithm.
  • the initial phase may be corrected using the lens module 1200 that may be located at one end of the scanning unit 1100. For example, by providing a pattern on the lens module 1200 positioned at one end of the scanning unit 1100, the initial phase may be corrected using the pattern as a reference image. Alternatively, a filter that can be mounted on the lens module 1200 or at one end of the scanning unit 1100 may be provided, and the initial phase may be corrected using the filter.
  • FIG. 40 is a diagram illustrating a fine patterning forming part 5100 appearing on a path of light irradiated according to a predetermined pattern when patterning is performed on one component of the scanning module 110 including the lens module 1200 (hereinafter, a pattern of light). ).
  • the pattern to which light is irradiated is various including a spiral pattern or a raster pattern. It may be a type of scanning pattern.
  • the fine patterning forming part 5100 shown in FIG. 40 is shown as a letter, but is not limited thereto, and the fine patterning forming part 5100 may include a shape that can be a reference image.
  • a light pattern may be formed in a square area, but the present invention is not limited thereto, and a light pattern may be formed in various shape areas.
  • the scanning unit 1100 is driven, the light pattern is irradiated toward the object O, and the fine patterning forming unit 5100 may not change according to the light pattern.
  • the fine patterning forming unit 5100 obtains fine patterning, which is an image corresponding to the fine patterning forming unit 5100, from the controller 130. It may appear on the image.
  • the fine patterning forming part may be disposed in various positions within the scanning module 110. Specifically, the fine patterning forming part may be located on the lens module 1200, but is not limited thereto, and may be located on the scanning part 1100. Alternatively, the fine patterning formation part is a separate structure The image may be present, and the structure may be coupled to one end of the scanning module 110 and used to correct the initial phase.
  • the fine patterning forming part 5100 will be described as being positioned on the lens module 1200.
  • the fine patterning forming part 5100 existing on the lens module 1200 may exist at a position where the pattern of light passes, and when the scanning module 110 performs scanning, the shape of the object O Regardless, it can provide consistent fine patterning. Accordingly, using the fine patterning as a reference image, the initial phase correction may be performed so that the fine patterning of the image obtained by the control unit 130 is consistent with the fine patterning appearing in the original fine patterning forming unit 5100.
  • the fact that the fine patterning of the acquired image and the fine patterning appearing in the fine patterning forming unit 5100 can be matched when the controller 130 acquires light-receiving information based on the light returned from the object O.
  • the information on the pixel of the portion where the fine patterning is predicted to appear in the image obtained by the control unit 130 corresponds to the information of the pixel according to the fine patterning provided by the fine patterning forming unit 5100 or more. I can.
  • the material constituting the fine patterning forming unit 5100 so that the pattern of light passes and an image according to the fine patterning forming unit 5100 can be obtained by the control unit 130 It may be made of a material that absorbs, reflects, or generates fluorescence.
  • the fine patterning forming unit 5100 when the fine patterning forming unit 5100 is made of a material that absorbs the light irradiated from the scanning unit 1100, the fine patterning forming unit 5100 can absorb the irradiated light, and the light is absorbed. Light may not return from the fine patterning formation part 5100.
  • the absorption of light by the fine patterning forming unit 5100 may mean that the light cannot return from the fine patterning forming unit 5100 by absorbing a specific wavelength band of light.
  • a specific wavelength is absorbed and the wavelength according to the shape of the fine patterning on the fine patterning forming unit 5100 cannot be obtained. Contrast may occur as much as the portion due to fine patterning. Accordingly, a portion according to fine patterning is obtained from the obtained image, and the phase may be corrected so that the portion according to the fine patterning of the image obtained through the obtained image corresponds to the fine patterning of the fine patterning forming unit 5100.
  • the fine patterning forming unit 5100 may reflect the irradiated light, and irradiated from the fine patterning forming unit 5100 All of the light can come back.
  • reflecting light by the fine patterning forming unit 5100 may mean that the light reflects a specific wavelength band of light and returns to the same wavelength as the wavelength of light irradiated from the fine patterning forming unit 5100. Accordingly, since the wavelength according to the fine patterning forming unit 5100 obtained by the control unit 130 that generates an image using a specific wavelength of light may not be a specific wavelength for generating an image, fine patterning is formed in the obtained image.
  • the contrast may occur as much as a portion of the portion 5100 according to fine patterning. Accordingly, a portion according to fine patterning is obtained from the obtained image, and the phase may be corrected so that the portion according to the fine patterning of the image obtained through the obtained image corresponds to the fine patterning of the fine patterning forming unit 5100.
  • the fine patterning formation part is made of a material that generates fluorescence using irradiated light
  • light returned from the fine patterning formation part 5100 may be fluorescence.
  • the fine patterning forming unit 5100 when the fine patterning forming unit 5100 generates fluorescence, the irradiated light is absorbed and the fine patterning forming unit 5100 generates light having a wavelength different from the absorbed light, so that the light forms fine patterning. It may mean returning to a specific wavelength from the part 5100.
  • the fluorescent material used for the fine patterning formation part 5100 a material expressed in light having wavelengths of 405 nm, 488 nm, and 785 nm may be used.
  • control unit 130 that generates an image using light according to a specific wavelength caused by a fluorescent material
  • light according to the wavelength according to the fine patterning forming unit 5100 may be obtained, so that fine patterning in the obtained image Contrast can occur as much as the part according to.
  • a portion according to the patterning shape may be obtained from the obtained image, and the phase may be corrected so that the portion according to the fine patterning of the image obtained through the obtained image corresponds to the fine patterning of the fine patterning forming unit 5100.
  • the phase correction is such that the control unit 130 acquires an image in which fine patterning appears, and the image in which the obtained fine patterning appears and the shape of the fine patterning on the fine patterning forming unit 5100 correspond to a predetermined level or more. It may be corrected by the control unit 130. Specifically, the fine patterning shape on the fine patterning forming part 5100 may be obtained by the control unit 130, and accordingly, the control unit 130 drives the scanning unit 1100 to obtain fine patterning and preliminary patterning on the image. By comparing the obtained fine patterning patterns by the control unit 130, a degree corresponding to each other may be obtained.
  • the phase of the driving signal may be changed and the comparison may be performed again.
  • the controller 130 may obtain an image of the object O by using the changed driving signal as a corrected phase value.
  • the phase of the driving signal may be changed using the input unit 140 on the controller 130, but the present invention is not limited thereto, and the phase may be automatically corrected using an algorithm.
  • phase correction using fine patterning is not limited to initial phase correction, and phase correction using fine patterning is possible even while scanning the object O is in progress.
  • the cut-off may mean that an image of the object O may not be obtained from a part of the edge by providing a part of the edge of the light pattern with a material that absorbs, reflects, or emits light.
  • the cut-off filter may be positioned on the lens module 1200, but is not limited thereto and may be positioned on the scanning unit 1100.
  • the cut-off filter is a separate structure The image may be present, and the structure may be coupled to one end of the scanning module 110 and used to correct the initial phase.
  • the cut-off filter will be described as being positioned on the lens module 1200.
  • the cut-off filter since the cut-off filter exists on the edge of the optical device, when the light is irradiated from the scanning unit 1100, the cut-off filter absorbs and reflects the light in a portion where the density of the light is increased. Or it can generate fluorescence. Accordingly, when the density of the irradiated light increases, photo bleaching in which the fluorescent material may be damaged in the object O, or photo damage in which the object O itself may be damaged due to high light intensity ( photo damaging), etc. may not occur.
  • the light-receiving unit 123 of the image generating module that generates an image using a specific wavelength of light may not be able to obtain light-receiving information. have. Specifically, the light absorbed or reflected from the cut-off corner does not reach the light receiving unit 123 and thus does not generate light reception information, and thus, the pixel value according to the corner does not appear in the image obtained by the control unit 130. , May be marked as an unused area.
  • the constituent material of the cut-off filter is made of a material that emits fluorescence
  • light returned from the object O may have a specific wavelength that can be obtained by the light receiving unit 123.
  • the light-receiving unit 123 may obtain the fluorescence of the cut-off corner as light-receiving information, and accordingly, the pixel value according to the corner portion of the image obtained by the control unit 130 may be obtained in the form of an unused area. .
  • FIG. 42A is a diagram illustrating an unused area according to a cut-off filter in an image obtained when a phase of a scanning unit driving signal or a scanning unit output signal is delayed.
  • FIG. 42B is a diagram illustrating an unused area according to a cut-off filter in an image obtained when the phase of the scanning unit driving signal or the scanning unit output signal is corrected.
  • the image obtained is not the original cut-off part.
  • There may be an unused area due to cut-off in the space of Accordingly, when the acquired image is checked and the portion where the unused area due to cut-off occurs in an arbitrary space in the acquired image, not the edge of the acquired image, the scanning unit driving signal or the scanning unit output signal The phase may be delayed.
  • the controller 130 may obtain information on an unused area in an image acquired by the controller 130 according to the cut-off filter.
  • the control unit 130 may obtain a degree of the existence of an unused area on the edge of the acquired image.
  • the degree of the existence of the unused area at the corner obtained by the control unit 130 is less than a certain level, by changing the phase of the driving signal, the control unit 130 may obtain the degree of the existence of the unused area at the corner again. .
  • the adjusted phase of the driving signal is used as a phase value to be corrected, and the controller 130 generates an image of the object O. Can be obtained.
  • changing the phase of the driving signal may be performed using the input unit 140 on the control unit 130, but is not limited thereto, and the phase may be automatically corrected using an algorithm.
  • the phase may be corrected by using the input unit 140 with the driving signal of the image in which the phase of FIG. 42 (a) is delayed.
  • the control unit 130 acquires the image according to FIG. 42 (a)
  • the phase of the driving signal may be adjusted using the input unit 140.
  • the control unit 130 may obtain an image in which the phase is corrected according to FIG. 42B.
  • the phase may be corrected for the driving signal of the image in which the phase of FIG. 42 (a) is delayed using an algorithm for phase correction described below.
  • the scanning module 110 may perform scanning on the object O, and the controller 130 may acquire an image according to the scanning.
  • the mounting device 5200 may be used to mount the unused scanning module 110.
  • the phase of the driving signal may be corrected in the mounting device 5200 on which the scanning module 110 is mounted.
  • a reference image is provided on the device 5200 on which the scanning module 110 is mounted, and a phase may be corrected based on the reference image. Specifically, when there is a phase delay in the driving signal of the scanning unit and the output signal of the scanning unit, the phase of the driving signal may be corrected so that the image obtained by the control unit 130 may match the reference image.
  • the phase of the driving signal may be corrected using the input unit 140 on the control unit 130 or the phase of the driving signal may be corrected using a phase correction using an algorithm.
  • the mounting device 5200 may include a receiving part 5210, a coupling part 5220, a reference pattern part 5230, or an adjustment part 5240.
  • the receiving part 5210 of the scanning module 110 mounting device 5200 may accommodate the scanning module 110.
  • the accommodation part 5210 may include a housing for receiving the scanning module 110.
  • the coupling portion 5220 of the scanning module 110 mounting device 5200 prevents the scanning module 110 accommodated in the receiving portion 5210 from being separated from the receiving portion 5210, or the scanning module 110
  • the scanning module 110 accommodated in the receiving part 5210 may be coupled to be fixed at a specific position of the receiving part 5210.
  • the reference pattern part 5230 of the scanning module 110 mounting device 5200 may provide a reference image so that the controller 130 can correct the phase of the driving signal while the scanning module 110 is mounted. have.
  • the adjusting unit 5240 of the mounting device 5200 of the scanning module 110 5200 can provide a configuration for focusing.
  • the accommodating part 5210, the coupling part 5220, the reference pattern part 5230, and the adjusting part 5240 will be described in detail.
  • 44 is a diagram illustrating that the scanning module 110 is accommodated in the image generating apparatus.
  • the receiving portion 5210 of the mounting device 5200 on which the scanning module 110 can be mounted may be provided on the image generating device.
  • the scanning module 110 may be mounted on the receiving portion 5210 of the mounting device 5200 on the image generating device of FIG. 44. Further, it is not limited to the position on the image generating device according to FIG. 44.
  • the receiving portion 5210 of the mounting device 5200 on which the scanning module 110 can be mounted may be located at a physically different position from the image generating device.
  • the receiving unit 5210 of the mounting device 5200 present at a location different from the image generating device may be connected to the image generating device, and accordingly, the mounting device 5200 through the control unit 130 of the image generating device Can be controlled.
  • the receiving unit 5210 may accommodate the entire scanning module 110, but is not limited thereto, and accommodates only a part of the portion irradiated with light from the scanning module 110, and thus a driving signal, a scanning unit driving signal, or scanning It is possible to correct the phase delay of the sub-output signal.
  • FIG. 45 is a view in which the scanning module 110 is mounted on the mounting device 5200.
  • FIG. 46 is a view showing a direction as viewed from the entrance of the receiving portion 5210 of the receiving portion 5210 of the mounting device 5200.
  • the coupling member 5250 may be provided on the scanning module 110.
  • the coupling member may be coupled to the coupling portion 5220 of the mounting device 5200, and accordingly, the scanning module 110 may be coupled to the mounting device 5200 at a predetermined angle.
  • the coupling portion 5220 of the coupling member and the mounting device 5200 may have the same shape so that the scanning module 110 and the mounting device 5200 can be coupled, or the shape of the coupling member
  • the coupling portion 5220 may be present in a shape that may include.
  • the coupling part 5220 of the mounting device 5200 has a square shape that can accommodate a square, or has a shape circumscribed to the square shape of the coupling member.
  • the present invention is not limited thereto, and may be a shape in which the coupling portion 5220 of the mounting device 5200 and the coupling member are coupled, including the shape of the coupling member.
  • the coupling member of the scanning module 110 and the coupling portion 5220 of the mounting device 5200 may be various members having a coupling force so that they may be coupled to each other.
  • the coupling member of the scanning module 110 and the coupling portion 5220 of the mounting device 5200 may be formed of a magnetic member. As the magnetic force exists between the coupling member and the coupling portion 5220, when the scanning module 110 is coupled onto the receiving portion 5210 of the mounting device 5200, it may be coupled to a specific position of the receiving portion 5210. I can. In addition, as the magnetic force is present, the coupling member and the coupling portion 5220 may be automatically coupled to fit a specific position.
  • a reference pattern part 5230 may be provided to the mounting device 5200 so that the controller 130 may perform initial phase correction.
  • the reference pattern part 5230 may be provided in a space on the mounting device 5200, but hereinafter, for convenience of description, it will be described that the reference pattern part 5230 is provided at the lower end of the mounting device 5200.
  • the lower end of the mounting device 5200 is the bottom surface of the receiving portion 5210 on an extension line in the direction in which light is irradiated from the scanning module 110. I can.
  • the scanning module 110 when the scanning module 110 is mounted on the mounting device 5200, the scanning module 110 directs light toward the reference image 5231 of the reference pattern portion 5230 provided at the bottom of the mounting device 5200. After irradiation, an image can be acquired using the returned light.
  • the acquired image when there is a phase delay in the scanning unit driving signal or the scanning unit output signal, the acquired image may be a phase delayed image.
  • the controller 130 may correct the phase of the driving signal, the scanning unit driving signal, or the scanning unit output signal so that the acquired image may match the reference image 5231.
  • the reference image 5231 may be one or more circular patterns in order to always provide a constant image regardless of the angle at which the scanning module 110 is mounted on the mounting device 5200.
  • the present invention is not limited thereto, and may be a predetermined reference image 5231.
  • the scanning module 110 may not be mounted at a predetermined position when mounted on the mounting device 5200.
  • the reference image 5231 may have a circular pattern so that initial phase correction can be performed even when the scanning module 110 is not mounted at a predetermined position.
  • the reference image 5231 may be made of a material that absorbs light irradiated from the scanning unit 1100. Specifically, when the reference image 5231 is made of a material that absorbs light irradiated by the scanning unit 1100, the reference image 5231 can absorb the irradiated light, and light is returned from the reference image 5231. May not come.
  • the reference image 5231 absorbs light it may mean that the light does not return from the reference image 5231 by absorbing a specific wavelength band of light. Accordingly, since the control unit 130 that generates an image using a specific wavelength of light cannot acquire the wavelength according to the reference image 5231, contrast may occur as much as a portion according to the reference image 5231 in the acquired image. . Accordingly, a portion according to the reference image 5231 is acquired from the acquired image, and the phase of the acquired image may be corrected.
  • the reference image 5231 may be made of a material that reflects light irradiated from the scanning unit 1100. Specifically, when the reference image 5231 is made of a material that reflects light irradiated from the scanning unit 1100, the reference image 5231 may reflect the irradiated light, and the light irradiated from the reference image 5231 All of this can come back.
  • reflecting light by the reference image 5231 may mean that the light reflects a specific wavelength band of light and returns to the same wavelength as the wavelength of the light irradiated from the reference image 5231.
  • the wavelength according to the reference image 5231 obtained by the controller 130 that generates an image using a specific wavelength of light may not be a specific wavelength, so that the obtained image is as bright and dark as the part according to the reference image 5231. This can happen. Accordingly, a portion according to the reference image 5231 is acquired from the acquired image, and the phase of the acquired image may be corrected.
  • the reference image 5231 may be made of a material that generates fluorescence.
  • the reference image 5231 when the reference image 5231 is made of a material that generates fluorescence using irradiated light, light returned from the reference image 5231 may be fluorescence.
  • the reference image 5231 when the reference image 5231 generates fluorescence, it absorbs the irradiated light and generates light having a wavelength different from that of the absorbed light, so that the light is specified from the reference image 5231. It could mean returning to wavelength.
  • the control unit 130 that generates an image using a specific wavelength originating from the fluorescent material can acquire the wavelength according to the reference image 5231, the contrast is as much as the portion according to the reference image 5231 in the acquired image. This can happen. Accordingly, a portion according to the reference image 5231 may be acquired from the acquired image, and the phase of the acquired image may be corrected.
  • the controller 130 acquires an image in which the reference image 5231 appears, and the image in which the reference image 5231 appears and the reference image 5231 present in the mounting device 5200 are predetermined. It may be corrected by the control unit 130 to correspond to a level or higher. Specifically, the reference image 5231 on the mounting device 5200 may be acquired by the controller 130, and accordingly, the reference image 5231 on the image obtained by the controller 130 driving the scanning unit 1100 ) And the reference image 5231 obtained in advance by the controller 130 may be compared to obtain a degree corresponding to each other. In this case, when the result of the comparison by the control unit 130 is less than or equal to a predetermined level, the phase of the driving signal may be changed and the comparison may be performed again.
  • the controller 130 may obtain an image of the object O by using the changed driving signal as a corrected phase value.
  • the phase of the driving signal may be changed using the input unit 140 on the controller 130, but the present invention is not limited thereto, and the phase may be automatically corrected using an algorithm.
  • the reference pattern unit 5230 may be provided with a structure according to a distance corresponding to the focal length.
  • FIG. 48 is a diagram illustrating that a reference image 5231 exists on the reference pattern part 5230 in a transparent structure.
  • an image may exist in the light transmitting structure 5235.
  • the light-transmitting structure 5235 may be glass or transparent plastic, but is not limited thereto. In the case of a material capable of transmitting light, the light-transmitting structure 5235 may be a material.
  • the reference image 5231 existing in the light transmitting structure 5235 may be provided according to the focal length of the lens module 1200, and the size of the reference image 5231 may decrease as the focal length increases.
  • the present invention is not limited thereto, and may increase as the focal length increases, and may also be provided in the same size.
  • the reference image 5231 may exist on the concave structure 5237.
  • the size of the reference image 5231 provided on the concave structure 5237 may decrease, so that as the focal length increases, a smaller reference image 5231 is provided.
  • the reference image 5231 may be drawn around the inside of the concave structure 5237, and the reference image 5231 drawn around the inside of the concave structure 5237 increases in size as the depth increases in the concave structure 5237. It can be made smaller.
  • a reference image 5231 having a different size for each depth may be provided, as shown in FIG. 47 mentioned above.
  • the controller 130 can acquire an image using light of a specific wavelength, when the reference image 5231 is provided by using a fluorescent material, the controller 130 acquires light reception information according to the reference image 5231 can do.
  • the reference image 5231 when the reference image 5231 is made of a fluorescent material, a fluorescent material such as IcG, 5-ALA, or FNa may be used, but is not limited thereto, and a material capable of emitting fluorescence according to irradiation of light is Can be used.
  • a fluorescent material when a fluorescent material is used in the reference image 5231, fluorescence may not appear according to continued use of the fluorescent material. Accordingly, it may be necessary to fill the fluorescent material.
  • a cartridge capable of additionally providing a fluorescent material may be provided.
  • the cartridge may be inserted or removed at the bottom of the mounting device 5200, but is not limited thereto, and is present on the top, the side of the mounting device 5200, or outside the mounting device 5200, so that a fluorescent substance is included in the reference image 5231. Can provide.
  • the cartridge is present at the lower end of the mounting device 5200.
  • the cartridge may have a structure including a fluorescent material in the cartridge, and when the fluorescent material is provided to the reference image 5231 and irradiated with light in the scanning module 110, the fluorescent image of the fluorescent material of the reference image 5231 is Can be obtained.
  • the reference image 5231 does not show fluorescence due to irradiation of light (for example, including a case where the fluorescent material is deformed by photo bleaching due to irradiation of light)
  • the mounting device 5200 The cartridge provided at the lower end of the is removed, and a cartridge containing a fluorescent material capable of displaying fluorescence may be newly inserted.
  • the present invention is not limited thereto, and the cartridge may be provided outside the mounting device 5200 to continuously supply a fluorescent material to the reference image 5231.
  • the mounting device 5200 may include an adjustment unit 5240 to provide a reference image 5231 suitable for the focal length of the lens module 1200 of the scanning module 110.
  • the adjustment unit 5240 may provide the reference pattern unit 5230 provided with the reference image 5231 according to the focal length, so that the position of the reference pattern unit 5230 is positioned at the lens module 1200 of the scanning module 110. ) Can be controlled to be closer or farther away.
  • the adjustment unit 5240 may be required so that the reference pattern unit 5230 in which the reference image 5231 exists can be adjusted according to the focal length of the lens module 1200.
  • 50(a) shows a reference pattern part 5230 at the lower end of the mounting device 5200 in order to provide a reference image 5231 suitable for the focal length of the lens module 1200, and the focal length is combined with the adjusting part 5240. It is a view showing that the reference pattern portion 5230 is adjusted in the entrance direction of the mounting device 5200 in order to fit.
  • 50(b) shows a reference pattern part 5230 present at the lower end of the mounting device 5200 in the direction of the lower end of the mounting device 5200 in order to provide a reference image 5231 suitable for the focal length of the lens module 1200 It is a diagram that expresses moving to.
  • the adjustment unit 5240 may be present to adjust the distance of the reference pattern unit 5230 existing at the lower end of the mounting device 5200.
  • the adjustment unit 5240 may be present at the lower end of the mounting unit, but is not limited thereto, and may be present outside the mounting device 5200 to adjust the position of the reference pattern unit 5230.
  • the adjustment module 5240 may include an adjustment module, and the adjustment module may be controlled by a user. According to the user's control, the adjustment module may adjust the reference image 5231 to fit the focal length of the lens module 1200.
  • providing the reference image 5231 according to the focal length of the lens module 1200 is to compare the image obtained by the control unit 130 with the reference image 5231, and the obtained image is compared with the reference image 5231. It may be to move the position of the reference pattern part 5230 to fit well.
  • the adjustment unit 5240 automatically includes the reference pattern unit 5230 so that the reference image 5231 existing on the reference pattern unit 5230 can be provided according to the focal length of the lens module 1200.
  • the position of the can be adjusted.
  • the adjustment unit 5240 present at the lower end of the mounting device 5200 may be provided with an electric or mechanical motor, and the motor may be configured so that the reference pattern unit 5230 can match the focal length of the lens module 1200.
  • the position of the reference pattern part 5230 can be adjusted.
  • adjusting the position of the reference pattern part 5230 to match the focal length of the lens module 1200 is not shown in the drawing, but control of the reference pattern part 5230 on the mounting device 5200 There may be a control unit for.
  • the stationary device 5200 may include a communication unit for communication with the image generating device, and the communication unit may communicate with the controller 130 of the image generating device by a wired or wireless communication method.
  • the communication unit of the control unit 130 of the image generating device acquires information on the position of the reference pattern unit 5230 from the control unit of the mounting device 5200, and the scanning module 110 irradiates and acquires light. The image to be used and the reference image 5231 may be compared.
  • the controller 130 of the image generating device may move by the adjusting part 5240 so that the adjusting part 5240 may be adjusted and match the focal length of the lens module 1200.
  • 51 is a diagram for explaining an initial phase correction method using a reference image 5231 existing in the mounting device 5200.
  • the initial phase correction method may be performed by the controller 130.
  • the initial phase correction method includes irradiating light to the reference pattern part 5230 in the scanning module 110 (S5000), and obtaining an image using the light returned from the reference pattern part 5230 (S5010). , Comparing the obtained image and the reference image 5231 (S5020 ), and correcting the phase of the driving signal based on the comparison result (S5030 ).
  • the controller 130 may apply a driving signal to the driving unit 1101.
  • the driving unit 1101 receives a driving signal and applies a scanning unit driving signal for driving the scanning unit 1100 to the scanning unit 1100, and the scanning unit 1100 receiving the scanning unit driving signal is a scanning unit.
  • Light may be irradiated to the object O according to the output signal.
  • phase correction when the phase correction is not performed, a phase delay may occur between the driving signal and the scanning unit driving signal or the scanning unit output signal. Accordingly, before the scanning module 110 is separated from the mounting device 5200 and scans the object O, the delayed phase may need to be corrected. This will be described below for convenience of description. It is explained by correction.
  • the initial phase correction is not performed, scanning of the object O is performed, and when phase correction using an algorithm is performed, a phase other than the phase value actually delayed between the driving signal and the output signal of the scanning unit is corrected.
  • the initial phase correction is performed in a situation where the scanning module 110 is not used, the time to search for the phase to be corrected during scanning may be shortened, and the control unit 130 may perform an image Can be obtained immediately.
  • the scanning module 110 is mounted on the mounting device 5200 In this state, light can be irradiated toward the reference pattern portion 5230. Specifically, when the scanning module 110 is mounted and the light is irradiated toward the reference pattern unit 5230, the light is continuously transmitted toward the reference pattern unit 5230 while the scanning module 110 is mounted.
  • the initial phase correction may be performed by irradiating light according to a preset period
  • the corrected image obtained by the controller 130 according to the initial phase correction is referred to as a reference image 5231
  • the degree of conforming to is equal to or less than the preset level
  • light may be continuously irradiated so that the image corrected to the preset level or higher may conform to the reference image 5231.
  • performing the initial phase correction by irradiating light according to a preset period may set an arbitrary time to a preset period, but is not limited thereto, and initial phase correction is continuously performed while the scanning module 110 is driven. Can be.
  • the scanning module 110 may also be operating.
  • the scanning module 110 may also stop the operation. Accordingly, when the scanning module 110 starts to operate again, the scanning unit before the scanning module 110 stops operation It may not be the same as the phase delay value of the output signal. Therefore, performing the initial phase correction by irradiating light according to a preset period may be possible until the scanning module 110 stops operating when the scanning module 110 continues to operate as the image generating device operates. I can.
  • the control unit 130 uses the light irradiated from the scanning module 110 and returned from the reference pattern unit 5230. Since the image obtained in may not correspond to the reference image 5231, the initial phase correction may be performed so that the image of the reference pattern unit 5230 and the image acquired by the controller 130 may correspond to each other.
  • the phase of the driving signal may be corrected using the corrected phase value obtained previously.
  • the control unit 130 uses the input unit 140 of the control unit 130
  • the phase of the driving signal, the scanning unit driving signal, or the scanning unit output signal may be adjusted so that the acquired image may match the reference image 5231.
  • the control unit 130 drives a driving signal and a scanning unit using an algorithm.
  • the delayed phase of the signal or the output signal of the scanning unit may be corrected.
  • the phase correction by the algorithm will be described below.
  • the driving signal and the scanning unit driving signal or the scanning unit output signal may have different phases.
  • the signal 5000 before the phase delay of FIG. 38 mentioned above may be a driving signal, and the signal 5001 after the phase delay may be a scanning unit driving signal or a scanning unit output signal.
  • the light irradiated by the scanning unit output signal from the scanning unit 1100 is returned from the object O by the interaction of the object with light including reflection, scattering, refraction, and diffraction from the object O, and the light receiving unit 123 may obtain light-receiving information using the returned light.
  • the control unit 130 may acquire an image using the light-receiving information.
  • the position according to the first signal may mean a position according to a signal applied in the direction of the first axis among the driving signals.
  • the position according to the second signal may mean a position according to a signal applied in the direction of the second axis, which is a direction orthogonal to the first axis among signals that control the driver 1101.
  • the acquired signal value may be a signal including light-receiving information acquired by the light receiving unit 123, but is not limited thereto, and information based on the returned light may be included in the acquired signal value.
  • the first axis direction may mean the x-axis in the Cartesian coordinate system
  • the second axis direction may mean the y-axis in the Cartesian coordinate system, but is not limited thereto, and an object using a scanning pattern
  • An arbitrary coordinate system such as a polar coordinate system for irradiating light to (O) may be included.
  • the first signal is applied in the direction of the first axis corresponding to the x-axis in the orthogonal coordinate system
  • the second signal is applied in the direction of the second axis corresponding to the y-axis in the orthogonal coordinate system.
  • the position according to the first signal may refer to the x-axis coordinate value of the image acquired by the controller 130
  • the position according to the second signal refers to the y-axis coordinate value of the image acquired by the controller 130. It can mean.
  • the position according to the first signal and the position according to the second signal may represent different coordinate values according to time.
  • the first axis direction and the second axis direction may be the same as the first axis direction and the second axis direction when the scanning unit 1100 is driven in the scanning module 110.
  • the image acquired by the controller 130 may include a plurality of pixels. Accordingly, the position according to the first signal and the position according to the second signal, that is, the x-axis coordinate value and the y-axis coordinate value of the image obtained from the control unit 130 are Can indicate location information.
  • a position according to a driving signal input from the controller 130 to drive the driving unit 1101 may be predetermined.
  • the controller 130 may apply a driving signal to the driving unit 1101 according to a preset period.
  • the controller 130 may acquire a location according to the first signal according to a preset period.
  • the preset period may be a frame rate (FR) for the image generating device to acquire an image.
  • the position according to the first signal may be expressed as the 1-1 position to the 1-n position according to n viewpoints corresponding to a preset period.
  • the n points of time corresponding to the preset period may be n points of time evenly distributed within the preset period, but are not limited thereto, and a plurality of predetermined points of time within the preset period may be n points of time.
  • the position according to the second signal may be expressed as a 2-1 position to a 2-n position according to n points of time corresponding to a preset period.
  • the driving unit 1101 inputs a driving signal of the scanning unit to the scanning unit 1100, and the scanning unit 1100 is driven by the driving signal of the scanning unit.
  • O) can be irradiated with light by the output signal of the scanning unit.
  • light irradiated to the object O and returned by the scanning unit output signal may be obtained in the form of light-receiving information through the light receiving unit 123.
  • the light-receiving information acquired by the light-receiving unit 123 may be acquired by the controller 130 as an acquired signal value.
  • the control unit 130 may acquire the first acquisition value to the n-th acquisition value as an acquisition signal value.
  • a format in which the position according to the first signal, the position according to the second signal, and the acquired signal values are acquired by the controller 130 is expressed as a data set.
  • the controller 130 may obtain position information of a pixel determined according to a position according to the first signal corresponding to the x-axis coordinate value and the position according to the second signal corresponding to the y-axis coordinate value in the image, An image may be provided using a data set obtained by matching the acquired signal values obtained sequentially to position information of a plurality of pixels.
  • control unit 130 acquires a phase-delayed image or a phase-corrected image
  • the driving signal, the scanning unit driving signal, or the scanning unit output signal may have different phases from each other.
  • a phase difference between the driving signal, the scanning unit driving signal, and the scanning unit output signal is expressed as a phase delay.
  • the meaning of the phase delay is that at a predetermined time point within a predetermined period, the position according to the first signal or the position according to the second signal, and the output signal of the scanning unit at the time point to the object O. It may mean that the passing locations are different from each other. Specifically, light may be irradiated to the object O by the scanning unit 1100 receiving the scanning unit driving signal and by the scanning unit output signal, which is a signal that is output as it is driven.
  • the control unit 130 may provide an image so that the acquired signal value corresponds to a pixel position of the image indicating the position according to the output signal of the scanning unit.
  • the image provided by the controller 130 may be an image in which a phase delay does not exist.
  • the first signal and the second signal of the driving signal may be used to specify the location information of the pixel in the image.
  • the control unit 130 uses the position according to the first signal and the position according to the second signal, and the acquired signal value.
  • the acquired image may be an image whose phase is delayed.
  • the controller 130 may obtain an image without a phase delay.
  • adjusting the phase so that the phase of the driving signal and the phase of the output signal of the scanning unit are equal to or higher than a predetermined level may be performed using the input unit 140 of the control unit 130 to adjust the phase of the driving signal.
  • the controller 130 may automatically adjust the phase of the driving signal using an algorithm.
  • phase correction adjusting the phase so that the phase of the driving signal and the phase of the output signal of the scanning unit correspond to a predetermined level or higher is referred to as phase correction.
  • 53 (a) is a diagram showing a data set of information that can be obtained when there is no phase delay.
  • 53B is a diagram showing a data set of information that can be obtained when there is a phase delay.
  • the position according to the first signal and the position according to the second signal are specified.
  • a plurality of acquisition signal values acquired at a location of a pixel may correspond to each other.
  • X1 which is a value obtained at a position according to a first signal in a data set
  • Y1 which is a value obtained at a position according to a second signal
  • an acquisition signal value of I1 may be obtained at a pixel location indicated by X1 and Y1.
  • the position according to the first signal and the position according to the second signal may appear repeatedly within a preset period, and accordingly, the position of the pixel specified through the position according to the first signal and the position according to the second signal May appear repeatedly.
  • X1 obtained at a position according to the first signal in the data set may be obtained at a position according to the first signal again after a predetermined point in time passes.
  • Y1 obtained at the position according to the second signal at the same time point at which X1 is obtained may be obtained at the position according to the second signal again after a predetermined time point has passed.
  • I1 which is the same acquisition signal value, is acquired at the pixel positions according to X1 and Y1 at different times, there may not be a phase delay between the driving signal and the scanning unit output signal.
  • a position according to the first signal and the position according to the second signal are used.
  • a plurality of acquired signal values acquired at a location may not correspond to each other.
  • X3 which is a value obtained at a position according to a first signal in a data set
  • Y1 which is a value obtained at a position according to a second signal
  • an acquisition signal value of I1 may be obtained at a pixel location indicated by X3 and Y1.
  • the position according to the first signal and the position according to the second signal may appear repeatedly within a preset period, and accordingly, the position of the pixel specified through the position according to the first signal and the position according to the second signal May appear repeatedly.
  • X1 obtained at a position according to the first signal in the data set may be obtained at a position according to the first signal again after a predetermined point in time passes.
  • Y1 obtained at the position according to the second signal at the same time point at which X1 is obtained may be obtained at the position according to the second signal again after a predetermined time point has passed.
  • values I2 and I3 are respectively obtained at pixel positions according to X1 and Y1 at different times, a phase delay may exist between the driving signal and the output signal of the scanning unit.
  • n obtained position values obtained at positions according to the second signal may be obtained at different positions by a degree of phase delay. For example, when a phase delay exists in the first signal among the driving signals, the value obtained at the 1-1 position is obtained at the 1-n position, and the value obtained at the 1-n position is the first It can be acquired at the -(n-1) position. Specifically, referring to FIGS. 52, 53 (a) and 53 (b), in order to correct the phase delay between the driving signal and the output signal of the scanning unit, the position according to the first signal in the data set Alternatively, n obtained position values obtained at positions according to the second signal may be obtained at different positions by a degree of phase delay. For example, when a phase delay exists in the first signal among the driving signals, the value obtained at the 1-1 position is obtained at the 1-n position, and the value obtained at the 1-n position is the first It can be acquired at the -(n-1) position. Specifically, referring to FIGS.
  • the controller 130 may obtain a position according to the first signal in the data set obtained by the controller 130 as values whose phase is adjusted.
  • the value obtained at the 2-1 position is obtained at the 2-n position, and the value obtained at the 2-n position is subtracted. It can be made to be acquired in the 2-(n-1) position. Specifically, referring to FIGS.
  • the control unit 130 may obtain a position according to the second signal in the data set obtained by the control unit 130 as phase-adjusted values.
  • the present invention is not limited thereto, and when a phase delay exists in both the position according to the first signal and the position according to the second signal of the driving signal, the values obtained at the position according to the first signal and the position according to the second signal are As long as the phase is delayed, it can be obtained at different locations.
  • n acquisition values obtained in the acquired signal value according to the light-receiving information may be acquired at the positions of different acquisition values as much as the phase is delayed.
  • I can.
  • a value acquired at the first acquisition value position may be acquired at the nth acquisition value position
  • a value acquired at the nth acquisition value position may be acquired at the (n-1)th acquisition value position.
  • the value of I1 obtained at the pixel position specified through X1 and Y1 is X1 and Y1 when the phase is delayed. It can be obtained at the pixel position specified through. That is, in FIG. 53(b), the acquired signal values sequentially acquired by the controller 130 may be adjusted so that I1 acquired as the first acquired value may be acquired as the second acquired value.
  • the controller 130 may obtain an image whose phase has been corrected using a position according to the first signal, the position according to the second signal, or an acquired signal value for which the phase is corrected.
  • the acquired signal value obtained by the controller 130 may be used.
  • the acquired signal value predicted to be acquired in the same pixel of the image acquired by the control unit 130 and the actual predicted time the controller 130 may obtain a phase delay value by using a difference value between acquired signal values including a standard deviation.
  • the controller 130 may obtain a phase delay degree by using a difference value between acquired signal values including standard deviations acquired in the same pixel of the image acquired by the controller 130.
  • obtaining the difference value between the acquired signal values is not limited thereto, and in addition to obtaining the standard deviation between the acquired signal values, the phase delay value using the absolute values of the average, variance, and difference values between the acquired signal values. Can be obtained. However, hereinafter, for convenience of description, it will be described as using the standard deviation to obtain a phase delay value.
  • a pixel hereinafter, a predicted pixel according to a prediction time
  • an acquired signal value at a prediction time is expected when a phase is delayed on a path of light irradiated by the scanning module 110 and an acquired signal value at an actual prediction time
  • the predicted pixel 5400 according to the prediction time point is on the path of light.
  • directions in which light travels at different viewpoints passing through the predicted pixel 5400 according to the predicted viewpoint on the light path may be a traveling direction including a first scanning direction and a second scanning direction.
  • a time point predicted to pass through the predicted pixel 5400 according to the predicted time point in the first scanning direction may be the first predicted time point, and the time point predicted to pass through the predicted pixel 5400 according to the predicted time point in the second scanning direction is It may be a second prediction time point.
  • the scanning unit output signal has a phase delay compared to the driving signal
  • the signal value 5410 obtained according to the first prediction time and the signal value 5420 obtained according to the second prediction time are expected according to the prediction time. It may not be a signal value corresponding to the pixel 5400.
  • 55 is a diagram illustrating a flow of correcting a phase by using a difference in signal values acquired at a prediction time point. Specifically, in order to correct the phase, selecting a pixel whose scanning direction crosses, obtaining a prediction time point, obtaining an acquired signal value 5410 according to a first prediction time point, and It may include obtaining the acquired signal value 5420, calculating a difference between the acquired signal values between prediction times, and correcting a phase.
  • the step of selecting a pixel at which the scanning direction crosses may include selecting a predicted pixel according to a prediction time point at which the first scanning direction and the second scanning direction meet.
  • different scanning directions may exist for a path of light passing through one pixel. Accordingly, in the case of a view passing through the predicted pixel 5400 according to a prediction point where the first scanning direction and the second scanning direction meet within one scanning pattern, the point of time passing through the predicted pixel according to the prediction point in the first scanning direction and The viewpoints passing through the expected pixels according to the prediction viewpoints in the second scanning direction may be different from each other.
  • one pixel position may be indicated at different prediction points of the driving signal. Accordingly, when the phases of the driving signal and the output signal of the scanning unit are different from each other, different acquired signal values according to the output signal of the scanning unit may represent different values. Therefore, the driving signal may be in the first scanning direction and the second scanning direction. You can select any pixel according to
  • step of obtaining a prediction time point (S5110) prediction by a first viewpoint and a second scanning direction that are expected to pass through the predicted pixel according to the prediction time by the first scanning direction in the driving signal It may include the step of acquiring a second viewpoint expected to pass through the predicted pixel according to the viewpoint. Specifically, since a phase delay may occur between the driving signal and the scanning unit output signal, when light is irradiated to the object O by the scanning unit output signal, an acquisition signal obtained according to the first and second viewpoints The values can be different.
  • a standard deviation between the acquired signal values obtained according to the output signal of the scanning unit may be obtained. Accordingly, a first view or a second view, which is a prediction time point predicted to pass through the predicted pixel according to the prediction time selected from the driving signal, may be obtained.
  • the steps of acquiring an acquired signal value according to the first prediction time point (S5120) and the step of acquiring the acquired signal value according to the second prediction time point (S5130) include:
  • the control unit 130 obtains the acquired signal value by irradiating light to (O) and using the returned light, the acquired signal value according to the first prediction time and the second prediction time according to the scanning unit output signal It may include the step of obtaining.
  • the phase of the driving signal and the phase of the output signal of the scanning unit may be different from each other, one signal value should be obtained from the predicted pixel according to the prediction time according to the driving signal, but the first prediction from the scanning unit output signal Signal values according to the viewpoint and the second prediction viewpoint may be different from each other.
  • the phase using the acquired signal value according to the first prediction time that can be obtained according to the first prediction time and the acquired signal value according to the second prediction time which can be obtained according to the second prediction time in the scanning unit output signal The delay value can be obtained.
  • the steps of acquiring the acquired signal values according to the first prediction time and the steps of obtaining the acquired signal values according to the second prediction time are sequentially shown, but the present invention is not limited thereto.
  • the step of acquiring the acquired signal value may precede the step of acquiring the acquired signal value according to the first prediction time point. Accordingly, there may be a first time point or a second time point predicted to represent the predicted pixel according to the predicted time point in the driving signal, and obtain a signal value obtained at the first time point or the second time point according to the output signal can do.
  • calculating the difference between the acquired signal values between prediction times includes calculating a standard deviation between the acquired signal values according to the first prediction time and the acquired signal values according to the second prediction time. It may be a step to do. Specifically, when a phase delay occurs between the driving signal and the output signal of the scanning unit, a signal value that could be obtained from the predicted pixel according to the prediction time according to the driving signal and the acquired signal value according to the first prediction time or the second prediction time The acquired signal values may be different from each other.
  • the acquired signal value according to the first prediction time and the acquired signal value according to the second prediction time are equal to or greater than a preset level
  • the acquired signal value according to the first prediction time and the acquired signal value according to the second prediction time are The image acquired by the controller 130 may represent the same pixel or a pixel adjacent to the predicted pixel according to the prediction time point. Accordingly, when the acquired signal value according to the first prediction time point and the acquired signal value according to the second prediction time point are equal to or greater than a preset level, the standard deviation between the value of the acquired signal may be small. Accordingly, when the standard deviation is small, the phase delay value between the driving signal and the scanning unit output signal may be small.
  • the standard deviation between the value of the acquired signal may mean that it is large. Accordingly, when the standard deviation is large, a phase delay value between the driving signal and the scanning unit output signal may be large.
  • the present invention is not limited thereto, and a phase difference between the driving signal and the output signal of the scanning unit may not be large even when the standard deviation is large.
  • the predicted pixel according to the prediction point may not be one pixel, and one or more pixels may be selected as predicted pixels according to the prediction point.
  • the degree of phase delay may be obtained by using all of the standard deviations between values of the acquired signals obtained through signals whose phase is delayed in the predicted pixels according to each prediction time point.
  • a value obtained at a position according to a first signal or a position according to a second signal is changed, or an acquired signal value is changed, and the standard deviation according to the prediction time point is changed.
  • the calculated value may include changing a position according to the first signal, a position according to the second signal, or an acquired signal value to a phase value equal to or less than a preset level.
  • a position according to the first signal or a value obtained at the position according to the second signal may be changed.
  • the predicted pixel according to the prediction time point may be selected again, and the standard deviation value at this time may be calculated.
  • a position according to the first signal or a position according to the second signal may be changed by changing the phase of the driving signal, and the controller 130 obtains an image whose phase is corrected. can do.
  • the controller 130 may acquire an acquisition signal value. Accordingly, the standard deviation between the acquired signal values acquired at the pixel positions for a predetermined time can be obtained, the phase of the driving signal is changed, and the phase of the driving signal is the phase when the obtained standard deviation value is less than a predetermined level.
  • the control unit 130 may obtain the changed image.
  • FIG. 56 is a diagram illustrating a flow of correcting a phase by using a standard deviation between acquired signal values acquired in pixels of an image acquired by the controller 130.
  • acquiring an acquisition signal value of one pixel for a preset time calculating a difference between the acquired signal values of the acquired pixels, and performing a predetermined number of pixels, It may include calculating a phase change value and correcting a phase.
  • acquiring an acquisition signal value of one pixel for a preset time may be a step of acquiring an intensity of light acquired by one of the pixels constituting an image.
  • the step of acquiring an acquisition signal value of one pixel for a preset time includes a location of a pixel that can be acquired based on a location according to a first signal and a location according to a second signal. It may include the step of obtaining an acquisition signal value that can be obtained from the light-receiving information.
  • the position according to the first signal may represent the x-coordinate in the pixel information of the entire image acquired by the controller 130
  • the position according to the second signal is y in the pixel information of the entire image acquired by the controller 130.
  • one pixel position may be determined based on the position according to the first signal and the position according to the second signal.
  • the position information of the pixel based on the position according to the first signal and the position according to the second signal of the driving signal may be obtained at least once during a predetermined time.
  • position information of one pixel may be obtained, and at this time, an acquisition signal value may be obtained from the position information of one pixel.
  • the controller 130 may acquire at least one acquisition signal value during a predetermined time.
  • the predetermined time may be a time when the position according to the first signal becomes the 1-1 position again, and the position according to the second signal becomes the 2-1 position again.
  • the present invention is not limited thereto, and may be a time in which a plurality of positions according to the first signal and the position according to the second signal are repeated, and may include an arbitrary time.
  • the acquired signal value may mean the intensity of light returned from the object.
  • calculating a difference between the acquired signal values of the acquired pixels may include calculating a difference between at least one acquired signal values acquired by the controller 130. Specifically, the controller 130 may calculate a difference between at least one acquisition signal value acquired at a location of one pixel based on a location according to the first signal and a location according to the second signal for a predetermined time.
  • the difference between the acquired signal values may be a difference value including standard deviation or variance.
  • it will be described as meaning a standard deviation between acquired signal values obtained by the controller 130.
  • the control unit 130 may include calculating, by the controller 130, a standard deviation of acquired signal values each obtained at a number of pixel positions or a plurality of randomly determined pixel positions.
  • the predetermined number or more of pixels for performing the calculation may be the position of one pixel among the images acquired by the controller 130, but is not limited thereto, and may include all pixels of the image acquired by the controller 130. have. Also, the predetermined number or more of pixels may include at least one or more pixel positions.
  • the step of performing calculation on a predetermined number of pixels includes not only calculating a standard deviation between acquired signal values obtained at each pixel position, but also calculating at each pixel position.
  • the control unit 130 may include obtaining one standard deviation information using standard deviations between the obtained signal values. For example, standard deviation information for all pixels may be obtained by using the standard deviation calculated at one pixel position. Specifically, when the controller 130 obtains one standard deviation information, it may be to obtain a sum of standard deviations obtained at each pixel position used for calculation.
  • the present invention is not limited thereto, and the controller 130 may perform various calculations including the average, product, variance, and standard deviation of standard deviations obtained at each pixel position.
  • acquiring one standard deviation information will be described as representing calculating the sum of the standard deviations acquired at each pixel position.
  • the control unit 130 obtains one standard deviation information by changing the position according to the first signal, the position according to the second signal, or the acquired signal value. It may include the step of. Specifically, the position according to the first signal or the position according to the second signal obtained by changing the phase of the driving signal is a pixel indicated by the position according to the first signal or the position according to the second signal before changing the phase of the driving signal. It may be different from the location information of.
  • the order of the acquired signal values acquired by the control unit 130 may not be changed, so that the position according to the position according to the first signal or the position according to the second signal of the driving signal whose phase is changed is acquired based on the position information of the pixel.
  • the signal value may be different from the acquired signal value before the phase is changed.
  • the standard deviation of the acquired signal value obtained at the pixel position based on the position according to the first signal and the position of the second signal for a predetermined time may be different from the standard deviation at the pixel position before the phase of the driving signal is changed.
  • one standard deviation information in a predetermined number of pixels may vary according to a phase change of the driving signal, and when the phase of the driving signal is continuously changed, at least one standard deviation information may be obtained.
  • the standard deviation in the pixel position based on the position according to the first driving signal and the position according to the second driving signal is close to zero.
  • the standard deviation between the acquired signal values acquired in one pixel it may mean that there is no difference between the acquired acquired signal values, and this may mean that there is no difference between the acquired signal values. It may indicate that the position indicated by the sub output signal is the same.
  • the standard deviation information using the acquired signal values acquired at a predetermined number of pixel positions it may mean that a phase delay occurs between the driving signal and the scanning unit output signal less.
  • the phase of the driving signal indicating the smallest standard deviation information among the standard deviation information of the driving signals whose phase is changed may be set as the phase changed by the controller 130.
  • the controller 130 may change the phase to the phase of the driving signal indicating standard deviation information corresponding to standard deviation information less than or equal to a preset level among standard deviation information of the driving signals whose phase is changed.
  • it will be described as meaning a phase at which the control unit 130 changes the phase of the driving signal having the smallest standard deviation information.
  • the step of correcting the phase may include changing the phase of the driving signal to the phase of the driving signal indicating the smallest standard deviation information.
  • the phase may be corrected by changing a value obtained at a position according to the first signal or a position according to the second signal of the driving signal, or by changing an acquired signal value.
  • the phase of the driving signal having the smallest standard deviation information may include both the phase of the first signal and the phase of the second signal among the driving signals.
  • the controller 130 may change the position according to the first signal according to the phase of the first signal having the smallest standard deviation information, and also, the second signal according to the phase of the second signal having the smallest standard deviation information. The position can be changed according to the signal.
  • changing the standard deviation information according to the smallest phase will be described as meaning phase correction of the driving signal.
  • the x-axis represents the phase according to the first signal
  • the y-axis represents the phase according to the second signal
  • a bright portion of FIG. 57 may indicate a value having a large standard deviation information
  • a dark portion may indicate a value having a small standard deviation information. Accordingly, in order to correct the phase of the first signal and the second signal of the driving signal, the phase according to the first signal and the phase of the second signal in the darkest part representing the smallest value of standard deviation information can be obtained. have.
  • the x-axis of FIG. 58 represents the phase according to the first signal
  • the y-axis represents the phase according to the second signal
  • the standard deviation information according to the change of the phase is indicated, so that the phase according to the first signal and the second signal
  • a bright part of FIG. 58 may indicate a value having a large standard deviation information
  • a dark part may indicate a value having a small standard deviation information. Accordingly, in order to correct the phase of the first signal and the second signal of the driving signal, the phase according to the first signal and the phase of the second signal in the darkest part representing the smallest value of standard deviation information can be obtained. have.
  • standard deviation information according to a first signal and a second signal whose phase is not corrected may be standard deviation information at a location where a black star exists.
  • a white star may represent a value having the smallest standard deviation information.
  • the control unit 130 changes the phase according to the first signal or the phase according to the second signal by a preset phase change period, while changing the phase of the first signal and the second signal at the black star.
  • the phase of the first signal and the phase of the second signal may be changed.
  • the control unit 130 determines the phase of the first signal in the black star and the phase of the second signal in the white star along the trajectory of the arrow in FIG. 58 by a preset phase change period. Changing the phase of the second signal can be expressed as a trajectory tracking method.
  • the trace for searching the phase of the first signal and the phase of the second signal whose standard deviation information is the smallest according to the trace tracking method is not limited to the trace of the arrow shown in FIG. It is changed by a preset phase change period in the direction of, and then changes by a preset phase change period in the direction of the phase according to the first signal, or in the direction of the phase according to the first signal and the phase according to the second signal. It may include changing the phase of the first signal or the second signal alternately by a preset phase change period.
  • the trajectory tracking method may be an algorithm for searching the phases of the first signal and the second signal having the smallest standard deviation information while changing the phase of the first signal or the phase of the second signal by a preset phase change period.
  • An algorithm for searching the phase of the first signal and the phase of the second signal having the smallest standard deviation information according to a preset phase change period will be described below.
  • the x-axis represents the phase according to the first signal
  • the y-axis represents the phase according to the second signal, indicating standard deviation information according to a change in the phase of the first signal and the second signal.
  • FIG. 59(b) represents the phase according to the first signal
  • the y-axis represents the phase according to the second signal, indicating standard deviation information according to a change in the phase of the first signal and the second signal.
  • This is a diagram showing a case in which the degree of change in the phase of the first signal or the second signal is large. Specifically, a bright part of FIG. 59B may indicate a value having a large standard deviation information, and a dark part may indicate a value having a small standard deviation information. Accordingly, in order to correct the phase of the first signal and the second signal of the driving signal, the phase according to the first signal and the phase of the second signal in the darkest part representing the smallest value of standard deviation information can be obtained. have.
  • a predetermined range is set from the phase of the first signal and the phase of the second signal according to the smallest standard deviation information when the degree of change in the phase of the first signal or the second signal is large
  • the process of searching for the phase of the first signal and the phase of the second signal indicating the smallest standard deviation information by setting the degree of change of the phase of the first signal or the second signal within the range is expressed by the range limitation method. .
  • the amount of standard deviation information that must be obtained from the controller 130 may be large.
  • time consumption for the control unit 130 to obtain the standard deviation information may increase.
  • the degree to which the phases of the first signal and the second signal are changed can be increased so that the control unit 130 consumes less time to obtain the standard deviation information, and at this time, the standard obtained by the control unit 130
  • the controller 130 may change the phase of the first signal and the phase of the second signal according to the deviation information.
  • the degree of change in the phase of the first signal and the second signal is large, the phase of the first signal and the phase of the second signal according to the smallest standard deviation information are changed in the phase of the first signal and the second signal.
  • the degree is small, the phase of the first signal and the phase of the second signal according to the smallest standard deviation information may be different.
  • the control unit 130 determines the smallest standard deviation information when the degree of the phase change of the first signal and the second signal is small. Standard deviation information due to the phase of the first signal and the phase of the second signal may not be obtained.
  • the degree to which the phases of the first signal and the second signal are changed is increased and a predetermined range is set, the smallest standard deviation information is obtained when the degree to which the phases of the first and second signals are changed is small.
  • the phase of the indicated first signal and the phase of the second signal may not be included in the corresponding range.
  • the time consumed by the control unit 130 is reduced, and the phase of the first signal and the second signal indicating the smallest standard deviation information when the phase of the first signal and the phase of the second signal are small
  • the controller 130 obtains the phase of the first signal and the phase of the second signal representing the smallest standard deviation information using a trajectory tracking method, and uses the range limitation method to perform a trajectory tracking method. Accordingly, the phase of the first signal and the phase of the second signal indicating the smallest standard deviation information within the obtained range may be obtained.
  • the standard deviation information is the most by using a predetermined phase change period. It is possible to search for the phase of the first signal and the phase of the second signal to be reduced.
  • the x-axis of FIG. 60 represents one of the phases of the first signal or the second signal
  • the y-axis represents standard deviation information
  • the phase of the first signal or the second signal with the smallest standard deviation information searched using the trajectory tracking method And, in the entire phase range of the first signal or the second signal, a diagram showing a phase having the smallest standard deviation information.
  • the black star of FIG. 60 may be the phase of the first signal or the second signal having the smallest standard deviation information searched using the trajectory tracking method
  • the white star is the total phase of the first signal or the second signal. It may be a phase when the standard deviation information is the smallest in a range.
  • a location of a black star and a location of a white star may be different from each other.
  • an initial delayed phase a phase delay between the driving signal and the scanning unit output signal
  • the phase of the first signal or the second signal having the smallest standard deviation information from the initial delayed phase is searched. Accordingly, when searching while changing the phase by a preset phase change period, the phase of the first signal or the second signal may be a phase indicated by the position of the black star.
  • the phase with the smallest standard deviation information to be searched is the first phase indicated by the position of the black star. It can be the phase of the signal and the phase of the second signal. Accordingly, the position of the white star in the case where the standard deviation information is the smallest in the entire phase range, which is a phase for generating a high-resolution image in which the phase is corrected as shown in FIG. 39 (b) mentioned above is indicated by the control unit 130 The phase may not be corrected.
  • the phase for correcting the phase of the driving signal is obtained by the controller 130 in a phase different from the phase according to the smallest standard deviation information among the entire phase range. minimum) is obtained.
  • the control unit 130 obtains a phase at which the standard deviation information is minimum by using a range limitation method after searching for a phase using a trajectory tracking method, according to a local minimum value
  • the phase can be obtained.
  • the phase of the first signal or the phase of the second signal having the smallest standard deviation information is obtained using the trajectory tracking method, and the phase of the first signal or the phase of the second signal obtained according to the trajectory tracking method is obtained in advance.
  • the phase of the first signal or the phase of the second signal having the smallest standard deviation information may be obtained by using the range limitation method as much as a set range.
  • the phase or the first signal having the smallest standard deviation information in the entire phase range 2 may not exist within a preset range. Accordingly, even when the phase of the first signal or the second signal having the smallest standard deviation information is searched using the range limitation method after the search according to the trajectory tracking method, the phase according to the local minimum value may be obtained.
  • a light portion and a dark portion indicating the degree of standard deviation information may be repeated in a certain pattern. Accordingly, in order to obtain the phase of the first signal or the second signal having the smallest standard deviation information in the entire phase range using the trajectory tracking method, a period in which the contrast is repeated in a constant pattern may be required.
  • the x-axis represents the phase according to the first signal
  • the y-axis represents the phase according to the second signal
  • FF is a pixel based on a position according to a first signal and a position according to a second signal among all pixels of the image to be generated by the control unit 130 when the scanning module 110 irradiates light toward the object O. You can indicate the percentage that it occupies.
  • the present invention is not limited thereto, and FF may indicate a ratio of an area occupied by a path through which light passes according to a scanning pattern within an area in which the scanning module 110 scans the object O. have.
  • a bright portion of FIG. 61 may indicate a portion having a high FF
  • a dark portion may indicate a portion having a low FF.
  • bright and dark areas are expressed as contrast.
  • the pattern in which the contrast of FIG. 57 appears and the pattern in which the contrast of FIG. 61 appears may be the same. Specifically, a period in which a bright portion indicated by a black arrow in FIG. 57 is repeated and a period in which a bright portion indicated by a black arrow in FIG. 61 is repeated may be the same. Accordingly, the period of light and dark repeated in a constant pattern of FIG. 57 can be calculated using the period of the pattern in which light and dark are repeated according to FIG. 61.
  • information on a driving signal generated by the controller 130 may be required in order to calculate a pattern in which FF according to FIG. 61 is repeated.
  • the controller 130 may use an AC signal as a driving signal. Accordingly, since the waveform of the AC signal can be repeated by a certain period, calculating a period in which the AC signal of the first signal or the second signal among the driving signals is repeated is a pattern in which the contrast is repeated in one axis direction in FIG. It can be obtained by the control unit 130.
  • the waveform of the AC signal from which the second signal is generated among the driving signals may be Equation 5.
  • Y may represent a position according to the second signal
  • A may represent the amplitude of the second signal.
  • the first signal can also be expressed as Equation 5, and the frequency component and phase component for expressing the position of the first signal can be expressed as a frequency component and a phase component along the x-axis direction. I can.
  • the second signal may repeat the same position according to the phase component of the second signal.
  • the phase component of the first signal is 0, the phase component of the second signal Is Can be repeated every time.
  • GCD maximum common divisor
  • the position according to the second signal is end Can be repeated every time, end In each case, the position according to the second signal may be repeatedly displayed.
  • the position according to the first signal may appear repeatedly, end In each case, the first signal may appear repeatedly.
  • the GCD is 1
  • the GCD is not 1, in order to repeat the position according to the first signal or the second signal
  • the phase can be repeated as many times as possible. here, Is Therefore, the period in which the phase component of the first signal or the second signal changes is In the case of, the position of the first signal or the second signal may be repeatedly displayed.
  • the preset phase change period is In the case of, the FF according to FIG. 61 may be repeatedly displayed. However, it is not limited thereto, and the preset phase change period is Even if it is an integer multiple of, FF may appear repeatedly.
  • the phase may be corrected by acquiring the phase of the first signal or the second signal having the smallest standard deviation information using the aforementioned preset phase change period.
  • a trajectory tracking method may be used based on a preset phase change period.
  • a preset phase change period may be used even when the range limitation method is used based on the phase acquired by the controller 130 by using the trajectory tracking method.
  • FIG. 62 is a diagram illustrating a flow for searching for a phase of a first signal or a second signal having the smallest standard deviation information when a trajectory tracking method is performed based on a preset phase change period. Specifically, like the aforementioned trajectory tracking method, the phase of the first signal or the second signal having the smallest standard deviation information in the phase direction of the first signal or the second signal can be searched based on a preset phase change period. have.
  • the first first signal to start the search may include the step of setting the phase of the second signal.
  • the controller 130 changes the phase component of the first signal or the second signal to a phase that is perpendicular to the phase component of the first signal or the second signal of the driving signal input to drive the driver 1101
  • a position according to the first signal or a position according to the second signal may be acquired by the controller 130.
  • the angle at which the phase components are at right angles to each other may mean 90 degrees, and may be an angle close to 90 degrees, which can be viewed as being substantially perpendicular.
  • the initial phase may be set so that the phase difference substantially close to 45 degrees may occur according to the direction in which the phase is searched, but the present invention is not limited thereto, and an initial phase may be set in the entire phase range. For example, when a signal having a resonant frequency is input to an object, the phase of a signal output according to the signal input to the object may be delayed by 90 degrees from the phase of the signal having the resonant frequency.
  • the control unit 130 takes the time required according to the trajectory tracking method. Can be reduced.
  • the controller 130 performs a first signal according to a phase change period in a phase direction according to a first signal or a phase direction according to a second signal.
  • it may include acquiring standard deviation information obtained by changing the phase of the second signal.
  • the first direction may be an x-axis indicating the phase of the first signal, or may be a y-axis indicating the phase of the second signal.
  • the second direction may be an x-axis indicating the phase of the first signal, or may be a y-axis indicating the phase of the second signal.
  • the first direction is the direction of the x-axis indicating the phase of the first signal
  • the second direction is the direction of the y-axis indicating the phase of the second signal
  • the controller 130 may change the phase of the driving signal in the first direction or the second direction by a predetermined phase change period, and may be expressed as moving.
  • the phase before the control unit 130 changes the phase of the driving signal in the first direction by a predetermined phase change period may be expressed as the phase before movement, and the phase of the driving signal is changed by a predetermined phase change period.
  • the phase after can be expressed as the phase after the shift.
  • the control unit 130 may obtain standard deviation information using the phase after moving in the first direction, and at this time, the phase in the second direction does not change, and only the phase in the first direction is changed to the phase. I can.
  • the step of comparing the standard deviation information before movement and the standard deviation information after movement includes standard deviation information according to the phase before movement and the phase after movement in the step of moving in the first direction.
  • the control unit 130 compares the standard deviation information. For example, if the standard deviation information according to the phase before moving in the first direction is greater than the standard deviation information according to the phase after moving in the first direction, the controller 130 determines the current phase after moving in the first direction. It is obtained as a phase of and the current phase in the first direction may be changed by a predetermined phase change period.
  • the controller 130 determines the current phase before moving in the first direction. Is obtained, and the current phase in the second direction may be changed by a predetermined phase change period.
  • the step of moving in the second direction includes the step of obtaining, by the controller 130, a phase in which the standard deviation information is the smallest in the first direction, and moving in the second direction. can do.
  • the control unit 130 obtains the phase of the first signal at which the standard deviation information is minimum by comparing the standard deviation information according to the phase shift in the first direction
  • the phase of the second signal in the second direction may be changed by a predetermined phase change period so that information of the standard deviation according to is minimized. Accordingly, the phase in the first direction does not change, and only the phase in the second direction may be changed by a predetermined phase change period, and the controller 130 uses the phase after moving in the second direction to obtain standard deviation information. Can be obtained.
  • the step of comparing the standard deviation information before movement and the standard deviation information after movement includes standard deviation information according to the phase before movement and the phase after movement in the step of moving in the second direction.
  • the control unit 130 compares the standard deviation information. For example, if the standard deviation information according to the phase before moving in the second direction is greater than the standard deviation information according to the phase after moving in the second direction, the controller 130 determines the current phase after moving in the second direction. It is obtained as a phase of and the current phase in the second direction may be changed by a predetermined phase change period. In addition, when the standard deviation information according to the phase before moving in the second direction is smaller than the standard deviation information according to the phase after moving in the second direction, the controller 130 determines the current phase before moving in the second direction. Can be obtained with.
  • the step of determining a phase correction value includes a phase of a first signal obtained by the controller 130 by moving in a first direction, and the controller 130 by moving in a second direction. It may include the step of correcting the phase of the driving signal using the phase of the second signal obtained by.
  • the standard deviation information according to the phase of the first signal after finally moving in the first direction and the phase of the second signal after finally moving in the second direction is the smallest standard deviation information within the entire phase range.
  • the phase of the first signal and the phase of the second signal acquired by the controller 130 may represent a degree in which the phase of the scanning unit output signal is delayed from the phase of the driving signal.
  • the phase of the driving signal may be corrected by using the phase of the first signal and the phase of the second signal acquired by the controller 130, and the controller 130 may correct the position of the driving signal according to the first signal and the second signal.
  • An image may be acquired or provided using a position according to a signal and an acquired signal value.
  • a method of searching for a phase having the smallest standard deviation information according to FIG. 62 may be the same as the search direction in FIG. 58 mentioned above.
  • FIG. 62 first, when the first direction, which is the direction in which the phase of the driving signal is moved, is the y-axis, as shown in FIG.
  • the controller 130 may search for a phase according to a path.

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Abstract

La présente invention concerne un dispositif optique. Un dispositif optique selon un mode de réalisation peut comprendre : une fibre optique ayant une partie d'extrémité fixe et une partie d'extrémité libre; une première unité d'actionnement formée de manière à appliquer une première force à une position d'actionneur entre la partie d'extrémité fixe et la partie d'extrémité libre de la fibre optique et à guider la partie d'extrémité libre de la fibre optique pour qu'elle se déplace dans une première direction; et une tige déformable disposée adjacente à la fibre optique et ayant une première partie d'extrémité et une seconde partie d'extrémité.
PCT/KR2020/001141 2019-05-02 2020-01-22 Dispositif de génération d'image Ceased WO2020222402A1 (fr)

Priority Applications (7)

Application Number Priority Date Filing Date Title
CN202080033166.7A CN113766866B (zh) 2019-05-02 2020-01-22 图像生成装置
AU2020266362A AU2020266362B2 (en) 2019-05-02 2020-01-22 Image generation device
EP24215231.2A EP4488935A3 (fr) 2019-05-02 2020-01-22 Dispositif de génération d'image
CA3132593A CA3132593A1 (fr) 2019-05-02 2020-01-22 Dispositif de generation d'image
CN202411605868.4A CN119279471A (zh) 2019-05-02 2020-01-22 图像生成装置
EP20798082.2A EP3936028A4 (fr) 2019-05-02 2020-01-22 Dispositif de génération d'image
AU2023200313A AU2023200313B2 (en) 2019-05-02 2023-01-20 Image generation device

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US201962842365P 2019-05-02 2019-05-02
US62/842,365 2019-05-02
KR10-2019-0112711 2019-09-11
KR1020190112711A KR102301809B1 (ko) 2019-05-02 2019-09-11 리사주 기반의 이미지 캘리브레이션 기술
KR10-2019-0150828 2019-09-11
KR1020190150828A KR102301808B1 (ko) 2019-05-02 2019-11-21 리사주 기반의 이미지 캘리브레이션 기술

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CN115278088A (zh) * 2022-08-19 2022-11-01 维沃移动通信有限公司 激光传感器、电子设备和对焦控制方法
US12585108B2 (en) 2019-05-02 2026-03-24 VPIX Medical Incorporation Image generating device

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KR20150107024A (ko) * 2014-03-13 2015-09-23 한국과학기술원 공진 주파수 변조 수단을 포함하는 광섬유 스캐너
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US20140232993A1 (en) * 2013-02-15 2014-08-21 Samsung Electronics Co., Ltd. Fiber scanning projector
KR20150052672A (ko) * 2013-11-06 2015-05-14 삼성전자주식회사 파이버 스캐닝 광 프로브 및 이를 구비한 의료 영상 기기
KR20150107024A (ko) * 2014-03-13 2015-09-23 한국과학기술원 공진 주파수 변조 수단을 포함하는 광섬유 스캐너
US20160051131A1 (en) * 2014-08-25 2016-02-25 Korea Advanced Institute Of Science And Technology Scanner for two-dimensional optical scanning, manufacturing method thereof, and medical imaging apparatus using the same

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US12585108B2 (en) 2019-05-02 2026-03-24 VPIX Medical Incorporation Image generating device
CN115278088A (zh) * 2022-08-19 2022-11-01 维沃移动通信有限公司 激光传感器、电子设备和对焦控制方法

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