JPH0529188B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an improvement in color shift correction of three laser beams for each of three primary colors in a color laser image recording apparatus.

(Prior Art) FIGS. 4 and 5 are diagrams showing the basic configuration of a conventional color laser printer. FIG. 4 shows a system using three lasers, a red laser 18, a green laser 19, and a blue laser 20, as laser light sources, which is called a three-tube system. Figure 5 shows red,
Helium-cadmium (He-Cd) white laser 1 that outputs white laser light containing the three primary colors of green and blue
This method uses one 7 unit and is called a single-tube type.

In the three-tube type, each color laser beam output from each laser is optically modulated by AOM (Acousto Optic Modulator) 16, 16', and 16'', respectively, corresponding to that color. The modulated laser beams of each color are reflected by the corresponding dichroic mirrors 14, 14', and 14'', and by aligning the optical axes at the time of reflection, The beam is then combined into a single beam, passes through an optical system, and is scanned by a deflector.
A color image is photosensitively formed on the surface of the photosensitive material 13.

In the single-tube type, one laser outputs laser light of three primary colors, red, green, and blue, as a single beam.

However, the intensity modulation by the color image signal of each color is
This must be done separately for each red, green, and blue laser beam. For this reason, dichroic mirror 15,
The laser beams 15' and 15'' are used to separate red, green, and blue laser beams. After separation, the configuration is similar to that of the three-tube type.

In this manner, in all conventional image recording apparatuses, three modulated laser beams of different colors are superimposed into one beam, and the same beam is irradiated onto the imaging plane.

A sensor (beam detection means) 1 for horizontal synchronization (H-Sync.) signals is placed in front of the image writing start point on the imaging plane, and from the detection signal output from this The generated synchronization signal is used to time the start of writing the image of one combined beam.

FIG. 6 is a diagram showing this time relationship.

Figure a shows the output waveform of the horizontal synchronization sensor 1, Figure b shows the scanning synchronization signal obtained by shaping the waveform in Figure A, and Figure c shows the image writing after a certain period of time _T0 has elapsed since the scanning synchronization signal. This indicates that image writing has started and continues for a predetermined period of time.

(Problems to be Solved by the Invention) However, in the above-mentioned conventional technology, it was difficult to completely overlap the three laser beams on the imaging plane. In order to completely overlap the three color beam spots on the imaging plane, the three laser beams must be completely overlapped using the dichroic mirrors 14, 14' and 14'' shown in Figures 4 and 5. is necessary, and very strict accuracy is required.For example, the spot diameter at the imaging plane must be
80 μm, the focal length of the f-theta lens is 200 mm, and the allowable color shift on the imaging plane is one-quarter dot. The setting angle error is approximately
Must be kept below 1/180 degree (20 seconds),
There is a problem in that the installation mechanism requires a high degree of processing precision, and the agency adjustment also requires a high degree of skill and man-hours.

In view of the problems of the prior art described above, an object of the present invention is to reduce the color shift of three color laser beams on the imaging plane.
It is an object of the present invention to provide a laser image recording device that can perform correction with simple means and with high precision.

(Means for Solving the Problems) In order to achieve the above object, the present invention has the following means configuration. That is, the laser image recording device of the present invention is an image recording device that records a color image on a color photosensitive material by simultaneously scanning a plurality of laser beams separated in the scanning direction and each having a different wavelength in the separated state. , 1 piece,
or a plurality of beam detection means provided corresponding to the plurality of laser beams; scanning synchronization whose waveform is shaped for each of the plurality of laser beams having different wavelengths in response to a beam detection signal from the beam detection means; a synchronization signal generation circuit that outputs a signal; receives each of the scan synchronization signals and a clock signal having a frequency that is an integral multiple of a preset pixel clock frequency, and outputs the clock signal from the time when each of the scan synchronization signals arrives; the plurality of pixel clock generation circuits that divide the frequency and generate pixel clock signals; and the beam scanning distance between the beam detection means and the image writing start position by receiving the pixel clock signals from each of the pixel clock generation circuits; a plurality of counting circuits that output a counting completion signal when counting has been completed for the number of pixels corresponding to the number of pixels; generating an image writing clock upon receiving the counting completion signal from each counting circuit; A laser image recording apparatus characterized by comprising: the plurality of image writing clock generation circuits that output the plurality of image writing clocks to a light modulation means that performs intensity modulation for each of the plurality of laser beams.

(Function) Hereinafter, the function of the laser image recording apparatus of the present invention having the above-described configuration will be described.

The present invention is based on the premise that the laser beams of multiple colors are not combined into one beam, but that the laser beams of each of the multiple colors are separated in the scanning direction. Separation here refers not only to cases in which the spots of each beam on the imaging plane are completely separated, but also to cases in which some of them overlap each other, as long as the beam detection means can distinguish and detect them. shall be included. Below, for convenience of explanation, 3
This will be explained using the case of color.

Now, the case where only one beam detection means is provided will be described. The image writing start position on the imaging surface of the photosensitive material must be the same for all three laser beams.

If the scanning speed of the laser beam is the same for all three laser beams, the time it takes for the laser beam to reach the image writing start position after passing through the beam detection means is independent of the magnitude of the deviation between the three beams. All three beams will be the same. Therefore, for each laser beam, when the arrival time has elapsed from the time when the beam detection means detects the passage of the beam, the light modulation means corresponding to the beam modulates the laser beam with the color image signal of that beam. As a result, both beams start writing an image from the same position, and even if the beams themselves are separated, no color shift occurs in the image recorded on the photosensitive material.

Next, a case will be described in which beam detection means are provided separately for each color of laser beam. In this case, since the positions of the beam detection means are different, the distance to the image writing start position is different, and the time from when the laser beam crosses the beam detection means to reaching the image writing start position is different. Become. Therefore, for each laser beam,
The three laser beams start writing from the same position by setting different waiting times from when the beam detection means detects the passage of the beam until the light modulation means starts modulating with the color image signal. It turns out.

In the case of one beam detection means, it outputs a detection signal every time a plurality of laser beams cross.

In the case of a plurality of color beams, a detection signal is output only when a beam of a color previously associated with the color beam crosses.

In either case, the detection signal is applied to a synchronization signal generation circuit, which outputs a waveform-shaped scanning synchronization signal for each color (wavelength) of the laser beam. The scanning synchronization signal for each color is sent to a pixel clock generation circuit provided for each color. A clock signal having a frequency that is an integral multiple of the pixel clock frequency is simultaneously applied to each of the pixel clock generation circuits from a stable oscillator or the like. Each pixel clock generation circuit divides the frequency of the clock signal from the time it receives each scan synchronization signal to generate a pixel clock signal. Note that the higher the frequency of this clock signal, the smaller the time difference between the scan synchronization signal and the first signal of the generated pixel clock signal.

This pixel clock signal is sent to a counting circuit provided corresponding to each pixel clock generation circuit. The counting circuit outputs a counting completion signal when it counts the sent pixel clock signals by a preset number. The time for counting this preset number corresponds to the elapse of the above-mentioned arrival time or waiting time.

Therefore, when the number of beam detection means is one, the setting values of all the counting circuits are the same.

On the other hand, if a beam detection means is provided for each color of the laser beam, the set numerical value of the counting circuit will also differ depending on the setting position.

The counting completion signal of each counting circuit is sent to the image writing clock generation circuit provided corresponding to each counting circuit, and the image writing clock generation circuit generates an image writing clock at the timing of the counting completion signal. and outputs it to the optical modulation means. In response to this clock signal, the light modulation means starts light modulation using the corresponding color image signal. As explained above, in the present invention, even if a plurality of laser beams of different colors have a color shift, since each beam starts writing on the photosensitive material from the same position, no color shift occurs. It turns out.

The reason why there is room for color shift when writing on photosensitive materials is due to the time difference between the scanning synchronization signal and the first pixel clock signal, but the maximum value of this time difference is divided by the period of the pixel clock signal. It is a value divided by the frequency ratio, and the color shift of the pixel at that time is 1/1 dot frequency division ratio. That is, if the frequency division ratio is 8, it will be a 1/8 dot, and if the frequency division ratio is 16, it will be a 1/16 dot.

Therefore, if the frequency of the clock signal is set high and the division ratio is increased, the color shift caused by the above-mentioned time difference can be ignored.

(Example) Hereinafter, an example of the present invention will be described based on the drawings. FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention. FIG. 2 is a diagram showing a scanning situation of a beam having a color shift in the present invention, in which a horizontal synchronization sensor 1 for detecting a passing beam is provided at a position on the left side (left margin) facing the photosensitive material 13. , red (R) laser beam 10, green
(G) The laser beam 11 and the blue (B) laser beam 12 sequentially start scanning across the horizontal synchronization sensor.

Now, when the three laser beams R, G, and B cross the horizontal synchronization sensor 1, a beam detection signal as shown in FIG. 3a is obtained from the horizontal synchronization sensor 1.

This beam detection signal is sent to the synchronization signal generation circuit 2, where the waveform is shaped to obtain the scanning synchronization signal shown in FIG. 3b. Among these scanning synchronization signals, the signal marked with R is sent to the pixel clock generation circuit 3, and the signal marked with B is sent to the pixel clock generation circuit 3''. A clock signal having a frequency that is an integral multiple (for example, 8 times, 16 times, etc.) of a preset pixel clock frequency is applied from a crystal oscillator 4 to the circuits 3, 3', and 3''.

The pixel clock generation circuits 3, 3' and 3'' divide the frequency of the clock signal to generate a pixel clock signal from when each horizontal synchronization signal arrives. Each of these pixel clock signals has a corresponding count. It is added to circuits 5, 5', and 5''.
Each counting circuit counts the pixel clock signal by the number of pixels corresponding to the scanning distance between the horizontal synchronization sensor 1 and the image writing start position on the photosensitive material 13, and outputs a counting completion signal when the counting is completed. The clocks are sent to the image writing clock generating circuits 6, 6' and 6'' corresponding to the counting circuits 5, 5' and 5'', respectively, and each image writing clock generating circuit generates an image writing clock. The image write clock generation circuit of this embodiment generates a clock signal and sends it to the corresponding AOM 7, AOM 7', and AOM 7''. The image writing clock is generated by taking the image writing clock.Each AOM modulates the amplitude of each laser beam for a certain period of time from the time when the image writing clock arrives, depending on the color image signal input separately. do.
FIG. 3c shows the time interval of image writing for each color. When there is one horizontal synchronization sensor, t ₁ = t ₂ =
t ₃ . When three horizontal synchronization sensors are used for each color, t ₁ , t ₂ , and t ₃ are values corresponding to the scanning distances between each horizontal synchronization sensor and the image writing start position.

Compared to the case of one horizontal synchronization sensor, it is more troublesome to adjust the setting value of the counting circuit, but a circuit for discriminating R, G, and B of the synchronization signal in the synchronization signal generation circuit is no longer necessary.

In addition, as a method of separately inputting the three color beams to the three horizontal synchronization sensors, something like a dichroic mirror may be used, or a filter that passes only the laser beam of each color may be used. good.

(Effects of the Invention) As explained above, in the apparatus of the present invention, the scanning distance between the fixedly provided horizontal synchronization sensor (beam detection means) and the image writing start position on the photosensitive material is fixed. By focusing on the fact that the laser beam crosses the horizontal synchronization sensor and starting image writing after the time corresponding to the scanning distance has elapsed, the laser beam is able to avoid color shift between the multiple primary color beams. Even if there are multiple beams, each beam will start writing after a certain period of time has passed after passing the horizontal synchronization sensor, so as long as the horizontal synchronization sensor can separate and identify each beam, there will be no difference between the beams. Since image writing is started from a point at the same distance from the horizontal synchronization sensor, that is, from the same position, regardless of the size or order of the images, there is an advantage that color shift does not occur when writing on the photosensitive material.

Even when horizontal synchronization sensors are provided for each color, the time from passing the horizontal synchronization sensor to starting writing depends on the scanning distance between each horizontal synchronization sensor and the image writing start position. If you set it,
Since the image writing start position on the photosensitive material is the same for each beam, there is an advantage that color shift does not occur.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing the configuration of an embodiment of the present invention, Fig. 2 is a scanning situation diagram of a beam with color shift, Fig. 3 is a time relation diagram between the scanning synchronization signal and the start of image writing, and Fig. 4 5 is a block diagram of a conventional three-tube color laser printer, FIG. 5 is a block diagram of a conventional single-tube color laser printer, and FIG. 6 is a time relationship diagram of scanning synchronization in the conventional apparatus. 1...Horizontal synchronization sensor (beam detection means), 2
... Synchronization signal generation circuit, 3, 3', 3'' ... Pixel clock generation circuit, 4 ... Crystal oscillator, 5, 5',
5''... Counting circuit, 6, 6', 6''... Image writing clock generation circuit, 7, 7', 7''... AOM, 8...
... Polygon, 9 ... f-theta lens, 10 ... Red laser beam, 11 ... Green laser beam, 12
...Blue laser beam, 13...Photosensitive material, 1
4, 14', 14'', 15, 15', 15''... Dichroic mirror, 16, 16', 16''...
AOM, 17...Helium-Cadmium (He-
Cd) White laser, 18...Red laser, 19
... Laser for green color, 20... Laser for blue color.

[Claims]

1 Consisting of a facsimile device 1 and a data processing device 2 connected to the facsimile device 1, the data processing device 2 receives and processes image data that is read by the facsimile device 1 and transmitted. and a data processing system that transmits and records processed data processed by the data processing device 2 to the facsimile device 1, the ability to indicate to the facsimile device 1 the reading ability and recording ability of the facsimile device 1. Ability data storage means 13 for storing data; Ability data control means 14 for reading out and transmitting the ability data stored in the ability data storage means 13 based on a request from the data processing device 2; and the data processing device. 2, a program storage means 21 in which a control program corresponding to the capability data of the facsimile device 1 is stored; A data processing system characterized in that the image data and processing data are controlled by a program.