JPH0694417A - Pointing device for spot light and measuring device for three-dimensional position - Google Patents

Abstract

(57) [Summary] [Object] To provide a spot light aiming device for projecting spot light to a desired position. [Structure] The projection optical axis of the spot light 18 and the spot image 1
1. The light projecting / imaging unit 5 is configured so that the imaging optical axis of the camera 4 for capturing the peripheral image of No. 1 is aligned, and the mirror 8 driven by the mirror driving unit so that the reflection angle is variable is arranged on the common optical axis. Thus, the spot light 18 is reflected on the object to be measured 13 and the image light from the object to be measured 13 is reflected on the camera 4. Since the projection angle of the spot light 18 and the image pickup angle of the camera 4 match, the image pickup image of the camera 4 is always located at the same position coordinate as the position change of the spot image 11 due to the change of the reflection angle of the mirror 8. When a certain image is obtained and the aiming position of the spot image 11 is coordinate-input on the image of the monitor 14, the driving amount of the mirror driving means for moving the spot image 11 is calculated by the calculating means based on the coordinate data. To be done.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional position measurement for non-contact measurement of a three-dimensional position or shape of an object at a distant position, or a projection position of spot light in laser processing for irradiating a laser beam. The present invention relates to a spot light aiming device for accurately determining a position and a three-dimensional position measuring device using the spot light aiming device.

[0002]

2. Description of the Related Art As a direct example of the necessity of projecting a spot light to a desired aiming position, the spot light is projected onto a measured object so that the three-dimensional position of the aiming point of the measured object, or A three-dimensional shape measuring device for measuring the shape of a measured object can be shown. The three-dimensional shape measuring apparatus shown below is a conventional apparatus that uses a spot light projection method for projecting spot light onto an object to be measured and measuring the three-dimensional position of the object to be measured according to the principle of triangulation. In FIG. 8, the three-dimensional shape measuring apparatus 51 uses a spot light 5 by a laser beam on an object to be measured 52.
Laser pointer 54 for projecting light 3 and the DUT 5
A laser tracker 56 for picking up a spot image 55 projected on the image 2 and a controller 58 for calculating the three-dimensional position of the object from the data obtained by controlling the laser pointer 54 and the laser tracker 56 are provided. The laser pointer 54 is an electronic theodolite with a spot light projector incorporated therein, and the laser tracker 56 is also an electronic theodolite with a TV camera incorporated therein, and the projection optical axis of the spot light or the imaging optical axis of the spot image is variable. Has been done. Further, the control device 58 is the laser pointer 5
4 and a motor controller that controls the electronic theodolite of the laser tracker 56 to operate each optical axis, an image processing device that detects a spot image obtained from the laser tracker 56, and a computer that controls these and performs a measurement operation. Is configured. In the above configuration, the laser pointer 54 projects the spot light 53 to emit the measured object 52.
The spot image 55 formed above is picked up by the TV camera of the laser tracker 56, and the position of the spot image 55 on the screen is detected from this image by the image processing device of the control device 58. The computer calculates the direction angle of the spot image 55 seen from the laser tracker 56 from the detection result of the image processing device, and the direction angle at which the laser pointer 54 projects the spot light 53 and the laser pointer 54 measured in advance. From the positional relationship between the laser tracker 56 and the laser tracker 56, the three-dimensional position of the spot image 55 on the object 52 to be measured is obtained by the principle of triangulation. Therefore, by providing the computer with data on the direction angle at which the laser pointer 54 projects the spot light 53 and a procedure for the laser tracker 56 to automatically track the spot image 55, the measured object 5
It is possible to automatically measure all the three-dimensional coordinates in two fixed areas, and the shape of the object to be measured 52 is measured.

[0003]

In the above-described three-dimensional measuring apparatus using the light spot, it is important that the laser pointer 54 can irradiate (or aim) the light spot at an arbitrary position on the object to be measured. , As the initial work, the light spot is guided to 6 characteristic points (angle of the measured object, part of the ridge, boundary of light and dark, etc.) on the measured object, and the control data of the laser projection optical axis at that time is given to the computer. It is necessary to determine the values of the calculation parameters used for triangulation. In the conventional laser pointer 54, when the laser projection optical axis is controlled as described above, the operator directly inputs the control data from the keyboard, so that the numerical value for correctly guiding the light spot to the characteristic point can be determined. It required skill and required a lot of time. The present invention was devised in view of the above problems, and an object thereof is to provide a spot light aiming device capable of projecting spot light for measuring a three-dimensional position to a desired position.

[0004]

To achieve the above object, the first means adopted by the present invention is a spot light source, a light source drive mechanism for changing the projection angle of the spot light source,
In a spot light aiming device comprising a camera for picking up a peripheral image of a spot image emitted from the spot light source to the object to be measured and a monitor for displaying the picked-up image of the camera, an arbitrary image on the pick-up screen of the camera Based on the coordinate input means for inputting the coordinates of and the input coordinate data,
The drive amount of the light source drive mechanism for moving the spot image to the position on the object under measurement corresponding to the input coordinates on the image pickup screen of the camera is calculated, and the drive amount is output to the light source drive mechanism. It is configured as a spot light aiming device characterized by comprising a computing means. The first means separates the spot light source, the light source driving mechanism and the camera from the coordinate input means and the monitor, and connects them by communication means, and changes the projection angle of the spot light source by remote control. It can be configured as a spot light aiming device. In addition, the second adopted by the present invention
Means comprises a spot light source and a camera for picking up a peripheral image of a spot image emitted from the spot light source on the object to be measured, so that the optical axis of the camera coincides with the optical axis of the spot light source. And a projection image pickup means which is a combination of the spot light source and the camera, and is provided on a common optical axis of the spot light source and the camera, and reflects the spot light from the spot light source and the image light from the DUT. A mirror, a mirror drive means for adjusting the reflection direction of the spot light by changing the tilt angle of the mirror, a coordinate input means for inputting coordinates on a monitor displaying an image captured by the camera, and the input means. The spot image is moved to a position on the DUT corresponding to the input coordinate on the display surface of the monitor, based on the coordinate data and the coordinate data of the captured spot image. It calculates the driving amount of the mirror driving means because, configured as a spot light aiming device characterized by comprising comprises a calculating means for outputting to said mirror driving means. A third means adopted by the present invention is a light source including a spot light source and a light source driving mechanism for changing a light projecting angle of the spot light source, and an object to be measured is irradiated from the spot light source. A camera that captures a peripheral image of a spot image, a monitor that displays the captured image of the camera, and a display surface of the monitor are divided into a required number of coordinate regions, and the amount of change in the projection angle of the spot light source for each coordinate region. By inputting an arbitrary coordinate area on the monitor, based on the coordinate input means for outputting the projection angle change amount of the input coordinate area, and the projection angle change amount, The drive amount of the light source drive mechanism for moving the spot image to the position on the object to be measured corresponding to the input coordinates on the display surface of the monitor is calculated, and the drive amount is output to the light source drive mechanism. With computing means Configured as a spot light aiming device, characterized by comprising comprises.
Further, the fourth means adopted by the present invention projects a spot light onto a desired portion of the object to be measured by a spot light source having a light source driving mechanism for changing the projection angle, and the camera emits the spot light. The peripheral triangulation image of the spot image is captured, and the principle of triangulation is calculated from the projection angle of the spot light source, the coordinates of the spot image captured by the camera on the monitor screen, and the distance between the spot light source position and the camera position. In a three-dimensional position measuring device for measuring a three-dimensional position of a desired part of the object to be measured based on, coordinate input means for inputting arbitrary coordinates on the image pickup screen of the camera, and based on the input coordinate data The drive amount of the light source drive mechanism for moving the spot image to the position on the object to be measured corresponding to the input coordinates on the image pickup screen of the camera is calculated, and the light source is calculated. Be by and a calculating means for outputting the driving amount to the moving mechanism constructed as a three-dimensional position measuring device according to claim.

[0005]

First, the operation principle of the spot light aiming according to the first means of the present invention will be described. FIG. 7 is a schematic diagram showing the operation principle. The spot light emitted from the spot light source forms a spot image at the point P _{0 of the} object to be measured. When the peripheral image centered on the spot image is captured by the camera, the visual field width A of the object to be measured centered on the spot image on the image capturing surface of the camera can be captured on the image capturing surface as the image width a. In order to specify the aiming position of the spot image on the imaging screen of this camera, the imaging screen is displayed on the monitor and the aiming position is specified by the coordinates on the monitor screen. For the designation of coordinates, for example, touch input by a touch panel provided on the monitor display surface can be adopted. If such a coordinate input means is used to designate the moving position of the spot image, that is, the aiming point as p ₁ , Coordinates on the monitor display surface (coordinates on the camera imaging surface) are detected and input to the calculation means. The calculation means calculates the drive amount of the light source drive mechanism for moving the spot image to the aiming position P ₁ on the measured object corresponding to the input coordinate based on the input coordinate data. Since the light source driving mechanism changes the projection angle of the spot light source by Δα based on the driving amount input from the calculation means, the projection angle of the spot light changes and the spot is spotted at the aiming point P ₁ on the object to be measured. An image is formed. Although the above is described as a one-dimensional object, as shown in FIG. 7, the visual field A × B of the object to be measured is captured as a × b on the image pickup screen of the camera, and this is displayed on the monitor as an X × Y display surface. , And the center point p ₀ on the display surface
Aim p moved from (image point at spot image position P ₀ )
_When the coordinate x × y of ₁ is input, the light source driving means changes the projection angle of the spot light source by the angles Δα and Δβ corresponding to x × y, and changes the spot image on the measured object from P ₀ to P ₁ . To move. The spot light source, the light source drive mechanism and the camera in the configuration of the first means are connected to the coordinate input means and the monitor by a communication means to isolate them from each other, and the spot light aiming by remote control and As a result, it is possible to perform three-dimensional position measurement, etc., and it becomes possible to perform spot light aiming operation in a safe area under dangerous conditions. According to the second means of the present invention, the projection optical axis of the spot light source that projects the spot light onto the object to be measured and the camera that captures the peripheral image of the spot image on the object to be measured by the spot light source. A projection image pickup means is formed so as to coincide with an image pickup optical axis, and a mirror driven by a mirror driving means is arranged on the common optical axis so that the spot light from the spot light source is measured. And the image light from the object to be measured is reflected to the camera.
The projection image pickup means and the mirror and the mirror driving means match the projection angle of the spot light source with the image pickup angle of the camera, and the image pickup of the camera is performed in accordance with the change of the position of the spot image due to the change of the reflection angle of the mirror. An image having a spot image at the same position coordinates can always be obtained. Therefore, when the aiming position of the spot image is coordinate-input on the image of the object to be measured by the coordinate input means on the monitor displaying the image picked up by the camera, the mirror driving means for moving the spot image based on the coordinate data. Is calculated by the calculating means. When the reflection angle of the mirror changes according to the calculated driving amount, the spot image moves, and the peripheral image of the moved spot image is captured by the camera at the same angle. Therefore, the aiming position of the spot light can be confirmed by the monitor. it can. Further, according to the third means of the present invention, the object to be measured is irradiated with spot light by the spot light source whose light source drive mechanism can change the projection angle, and a peripheral image of the spot image by the spot light is captured by the camera. Then, the captured image is displayed on the monitor. On the display surface of this monitor, the amount of change in the projection angle of the spot light is set for each coordinate area into which the display surface is divided into a required number. When an arbitrary coordinate area is input on the display image of the monitor, the calculation means moves the spot image to a position on the object to be measured based on the projection angle change amount set in the input coordinate area. The drive amount of the light source drive mechanism is calculated. The light source drive mechanism, to which this drive amount is input, changes the projection angle of the spot light source, so that the monitor confirms whether or not the moving position is the desired position. Further, according to the fourth means of the present invention, the spot light from the spot light source is projected onto a desired position of the object to be measured, and the peripheral image of the spot image is captured by the camera, whereby the projection angle and the imaging angle The spot light aiming device is applied to a three-dimensional position measuring device that calculates the three-dimensional position of the spot image position on the object to be measured based on the principle of triangulation from the distance between the spot light source and the camera. That is, by selecting the desired position of the object to be measured on the image pickup screen of the camera, the coordinate input means outputs the coordinate data of the desired position. This coordinate data is input to the calculating means, and the driving amount of the light source driving mechanism for moving the spot image to the position on the object to be measured corresponding to the input coordinates is calculated. Since the light source drive mechanism changes the projection angle of the spot light source with the calculated drive amount, the spot image moves to the desired position of the measured object. In this way, since the aim for moving the spot image to the desired position of the object to be measured can be set on the image pickup screen of the camera, the aim setting for the three-dimensional position measurement can be performed without requiring skill, and the position measurement operation can be performed. There is provided a three-dimensional position measuring device capable of performing accurately and easily.

[0006]

Embodiments of the present invention will be described below with reference to the accompanying drawings for the understanding of the present invention. The following embodiments are examples of embodying the present invention and do not limit the technical scope of the present invention. 1 is a schematic diagram showing the configuration of a spot light aiming device according to the first embodiment of the present invention, FIG. 2 is a front view of a monitor according to the first embodiment,
3 is an explanatory view showing a change of aiming by a touch panel according to the first embodiment, FIG. 4 is a schematic view showing a configuration of a spot light aiming device according to a second embodiment of the present invention, and FIG. 5 is a third view of the present invention.
FIG. 6 is a schematic diagram showing a configuration according to the third embodiment, and FIG. 6 is a front view of a monitor according to the third embodiment. In FIG. 1, a spot light aiming device 20 according to the first embodiment is a projection imaging unit (projection device) in which a spot light source for projecting spot light by a laser beam and an imaging device for imaging an object to be measured are integrally formed. The image pickup means) 5, the monitor 14, and the computer (calculation means) 17 are provided. The projection imaging unit 5 includes a laser oscillator 1, a beam expander 2, a fixed mirror 3, a beam splitter 6, a focusing lens 7, a variable angle mirror (mirror) 8 and a TV camera (camera) 4. The laser beam output from the laser oscillator 1 has its beam diameter expanded to about 20 mm by the beam expander 2, is reflected by the fixed mirror 3 and the beam splitter 6, and is further focused by the focusing lens 7
Are converged by and are incident on the variable angle mirror 8. The projection beam (spot light) 18 reflected by the variable angle mirror 8 is projected onto the object to be measured 13 and forms a spot image 11 on the object to be measured 13. The variable angle mirror 8 projects a shadow image of the periphery of the measured object 13 with the spot image 11 as the center.
8 is reflected in the incident direction. This image light is transmitted through the beam splitter 6, captured by the TV camera 4 and imaged.
The beam splitter 6 is an optical element formed so as to transmit only visible light except the wavelength of the laser beam and reflect the laser beam. An image of the DUT 13 taken by the TV camera 4 is displayed on the monitor 14.
If the image pickup range of the TV camera 4 is a field of view 12 (A × B) centered on the spot image 11, the spot image 11 is at the center on the screen of the monitor 14, and the angle of the variable angle mirror 8 is changed to project light. Even when the projection direction of the beam 18 is changed, the spot image 11 is always located at the center of the image of the DUT 13 displayed on the monitor 14. A touch panel (coordinate input means) capable of detecting a touch position with a predetermined resolution is mounted on the screen surface of the monitor 14, and when the screen is touched with a fingertip or a conductive touch stick (touch input), the touch panel is touched. The position is detected and position information is input to the computer 17 via the touch panel driver 15. The computer 17 calculates a control amount in the light projecting direction of the light projecting beam 18 based on this position information, and outputs a control signal to the motor drivers 16 of the motors 9 and 10 which drive the variable angle mirror 8.

The variable angle mirror 8 is equipped with a mirror driving means, and the mirror driving means constitutes a light source driving mechanism for changing the projection angle of the spot light source as described above, and at the same time, the imaging angle of the TV camera 4 is increased. Can be changed in accordance with the light projection angle. The mirror driving means is configured by including an α-axis rotation motor 9 for changing the mirror angle in the α-axis direction and a β-axis motor 10 for rotating the mirror angle in the β-angle direction. 1
The mirror angle is controlled by 6. Motor driver 1
Reference numeral 6 denotes a variable angle mirror 8 for rotating and driving the respective motors 9 and 10 based on a control signal inputted from the computer 17.
The light projection angle and the imaging angle of are changed. Computer 1
The calculation of the control amount of the variable angle mirror 8 by 7 is performed as follows. The screen size of the monitor 14 shown in FIG. 2 is X × Y, and the coordinate value on the screen input by touch is XX.
Let y be the sensing area of the CCD element which is the image pickup surface of the TV camera 4, and f be the focal length of the lens of the TV camera 4, then the optical axis drive amounts Δα, Δβ of the projection beam 18 by the variable angle mirror 8 are assumed. Is calculated by the following equations (1) and (2). The origin (0,0) of the screen coordinates is the position of the spot image 11 as described above. Δα = a · x / (f · X) ───── (1) Δβ = b · y / (f · Y) ───── (2) For example, consider the case of touch input in the upper right corner of the screen. , The coordinate values of the upper right corner are x = X / 2 and y = Y / 2, so if these are substituted into the equations (1) and (2), the projected beam 1
The optical axis drive amounts Δα and Δβ of No. 8 are expressed by the following equations. Δα = a / (2 · f) Δβ = b / (2 · f) When the distance from the variable angle mirror 8 to the object to be measured 13 is L and the variable angle mirror 8 is rotated by Δα and Δβ,
From the condition of (f << L), the movement of the spot image on the DUT 13 is expressed by the following equation. Δα-A / (2 · L) Δβ-B / (2 · L) That is, the object 13 moves by L times A / 2 and B / 2. Therefore, the spot image 11 moves to the point of the DUT 13 displayed in the upper right corner on the screen, and the image of the visual field centering on the moved spot image 11 is captured by the camera 4 and displayed on the monitor 14. It As can be seen from the above example, by controlling the rotation of the variable angle mirror 8 in accordance with the equations (1) and (2), it is possible to perform touch input at a desired position of the DUT 13 displayed on the screen of the monitor 14. , The spot image 11 can be moved to the position where the touch input is made (FIG. 3). That is, it is possible to easily move to a desired position of the spot image 11 without having to quantitatively know the control amount of the projection beam 18 by the variable angle mirror 8.

Next, a second embodiment of the present invention will be described. The same elements as those in the first embodiment are designated by the same reference numerals and the description thereof will be omitted. In FIG. 4, the spot light aiming device 40 according to the second embodiment has the same basic configuration as that of the first embodiment, and it is projected by means of radio wave communication or optical communication (transceivers 36, 37). The image pickup unit 35 and the control unit 34 are connected to each other, and aiming control is performed by remote control. TV
DUT 1 around spot image 11 captured by camera 4
The image of 3 is from the first transceiver 36 to the second transceiver 3
7, is input to the computer 38, and is displayed on the monitor screen of the computer 38. A touch panel is mounted on the surface of this monitor screen, and the control data of the projection beam 18 by touch input is stored in the computer 3
From the second transmitter / receiver 37 to the first transmitter / receiver 36, and the motor driver 15 controls the reflection angle of the variable angle mirror 8. Next, a third embodiment of the present invention will be described. The same elements as those in the first embodiment are designated by the same reference numerals and the description thereof will be omitted. In FIG. 5, the spot light aiming device 30 according to the third embodiment includes a light source unit 23, a monitor 14, and a computer 17. The light source unit 23 includes a laser oscillator 21, a beam expander 22, an α-axis rotating mechanism 25, and a β-axis rotating mechanism 24, and changes the projection angle of the projection beam 18. To form a spot image 11 on the object to be measured 13. An image around the spot image 13 of the DUT 13 is captured by the fixed TV camera 19, and the image is displayed on the monitor 14 having a touch panel mounted on the screen surface. Monitor 14
When touch input is performed on the screen of the computer, the touch panel position data is transferred to the computer 1 via the touch panel driver 15.
Input to 7. The computer 17 calculates the control amount of the projection beam 18 based on this position information, controls the rotation mechanism of the light source unit 23 by the motor driver 26,
The projection angle of the projection beam 18 is changed. The touch panel is divided into, for example, 7 × 7 = 49 regions as shown in FIG. 6, and the optical axis control amount Δα of the projection beam 18 is divided into regions.
The control amount of Δβ is set, and the computer 17
It is determined which of the 49 touch input data is touched, and the Δα and Δ set in that region are determined.
The control amount is output from the value of β to the motor driver 26. In the spot light aiming device 20 according to the first embodiment, the range for moving the spot image 11 each time is restricted within the imaging field of view 12, or the accuracy of the touch input position is the thickness of the fingertip. Spot image 11
The control accuracy of 1 also had a drawback that was influenced by this. This third
According to the embodiment, as shown in FIG. 6, since it is possible to adopt a range selection type in which an arbitrary control amount can be set for each area of the touch panel, the spot image 11 is moved to a desired position. Therefore, the number of touch inputs required increases, but the above-mentioned drawbacks are eliminated and the reliability of control can be improved. The spot light aiming device described above can be applied to the aiming device for forming a spot image at a desired position on the object to be measured by the laser pointer in the three-dimensional shape measuring device shown in the conventional example. In the conventional device, it is difficult to move the spot image to a desired position, and it requires skill to operate. However, by applying the spot light aiming device according to the present embodiment, it is easy to operate without requiring skill. It is possible to guide the spot image to a desired position.

[0009]

As described above, according to the present invention, when projecting the spot light onto a desired portion of the object to be measured, the operator touches the display surface while confirming the position of the spot image on the image monitor. The spot light projection position can be controlled by a simple operation. Therefore, it is possible to provide a spot light aiming device that simplifies the work that requires skill for setting the spot light aiming in the conventional three-dimensional position measurement, and at the same time, applies this spot light aiming device. The effect of facilitating the aiming operation of the three-dimensional position measuring device is exhibited.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a configuration of a spot light aiming device according to a first embodiment of the invention.

FIG. 2 is a front view of the image monitor according to the first embodiment.

FIG. 3 is an explanatory diagram showing a change in display on the image monitor according to the first embodiment.

FIG. 4 is a schematic diagram showing the configuration of a spot light aiming device according to a second embodiment of the present invention.

FIG. 5 is a schematic diagram showing the configuration of a spot light aiming device according to a third embodiment of the present invention.

FIG. 6 is an explanatory diagram showing division of the display surface of the image monitor according to the second embodiment.

FIG. 7 is a schematic diagram illustrating the operation principle of the spot light aiming device of the present invention.

FIG. 8 is a schematic diagram showing the configuration of a three-dimensional shape measuring apparatus.

[Explanation of symbols]

1, 21 ─ Laser oscillator 4, 19 ─ TV camera (camera) 5, 23, 35 ─ Spot light source 6 ─ Beam splitter 8 ─ Variable angle mirror (mirror) 9 ─ α axis rotation motor (mirror) Driving means / light source driving mechanism) 10-.beta.-axis rotating motor (mirror driving means / light source driving mechanism) 11-spot image 13-measurement object 14-monitor 16,26-motor driver 17,38- -Computer (arithmetic means) 20, 30, 40 --- Spot light aiming device 36 --- First transceiver (communication means) 37 --Second transceiver (communication means)

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yoshiro Nishimoto 1-5-5 Takatsukadai, Nishi-ku, Kobe Chome 5-22 Shinko Plant Construction Co., Ltd.

Claims (5)

[Claims] 1. A spot light source, a light source drive mechanism for changing a projection angle of the spot light source, a camera for picking up a peripheral image of a spot image emitted from the spot light source onto an object to be measured, and an image picked up by the camera. In a spot light aiming device comprising a monitor for displaying, a coordinate input means for inputting arbitrary coordinates on the image pickup screen of the camera,
Based on the input coordinate data, the drive amount of the light source drive mechanism for moving the spot image to the position on the object to be measured corresponding to the input coordinate on the imaging screen of the camera is calculated, and the light source is calculated. A spot light aiming device comprising: a driving mechanism; and an arithmetic means for outputting the driving amount. 2. The spot light source, the light source driving mechanism and the camera are isolated from the coordinate input means and the monitor, and the communication means are connected to each other, and the projection angle of the spot light source is changed by remote control. Item 2. The spot light aiming device according to item 1. 3. A spot light source and a camera for picking up a peripheral image of a spot image emitted from the spot light source onto the object to be measured, and the optical axis of the camera coincides with the optical axis of the spot light source. As described above, the projection imaging means formed by combining the spot light source and the camera is provided on the common optical axis of the spot light source and the camera, and the spot light from the spot light source and the image light from the object to be measured are provided. Mirrors for reflecting, mirror driving means for adjusting the reflection direction of the spot light by changing the tilt angle of the mirrors, coordinate inputting means for inputting coordinates on a monitor displaying an image picked up by the camera, and the inputting The spot image is moved to a position on the DUT corresponding to the input coordinate on the display surface of the monitor from the coordinate data thus obtained and the coordinate data of the spot image taken. A spot light aiming device, comprising: a calculating means for calculating a driving amount of the mirror driving means for outputting and outputting the driving amount to the mirror driving means. 4. A spot light source, a light source driving mechanism for changing a projection angle of the spot light source, a camera for picking up a peripheral image of a spot image irradiated from the spot light source on an object to be measured, and an image picked up by the camera. And a monitor that displays
The display surface of the monitor is divided into a required number of coordinate areas, the amount of change in the projection angle of the spot light source is set for each coordinate area, and an arbitrary coordinate area is input on the monitor to input. Coordinate input means for outputting the projection angle change amount of the coordinate area, and based on the projection angle change amount,
The drive amount of the light source drive mechanism for moving the spot image to the position on the object to be measured corresponding to the input coordinates on the display surface of the monitor is calculated, and the drive amount is output to the light source drive mechanism. A spot light aiming device comprising: a computing means. 5. A spot light source equipped with a light source drive mechanism for changing the light projection angle projects the spot light onto a desired portion of the object to be measured, and a camera captures a peripheral image of the spot image irradiated from the spot light source. Then, from the projection angle of the spot light source, the coordinates of the spot image captured by the camera on the monitor screen, and the distance between the spot light source position and the camera position, the object to be measured is based on the principle of triangulation. In a three-dimensional position measuring device for measuring a three-dimensional position of a desired part, coordinate input means for inputting arbitrary coordinates on an image pickup screen of the camera, and the spot image of the camera based on the input coordinate data. The drive amount of the light source drive mechanism for moving to the position on the DUT corresponding to the input coordinates on the imaging screen is calculated, and the drive amount is output to the light source drive mechanism. A three-dimensional position measuring apparatus comprising: a calculation unit that applies force.