JP2016057576A - Image display device and image display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device and method for drawing images, which prevent quality deterioration of drawn images caused by irradiation of laser light for detecting an output level of laser light.SOLUTION: An image drawing device 1 includes; a laser light source unit 3; a scanner unit 4 for reflecting and scanning laser light; a scanner control unit 7 which controls the scanner unit 4 to scan the laser light across a predetermined width; a laser light source control unit 6 which controls output timing and level of the laser light emitted from the laser light source unit 3 such that an image is drawn inside a scanning area of the scanner unit 4, and which provides control to have the laser light source unit 3 output characteristic detection laser light for detecting the output level of the laser light; and a characteristic detection control unit 8 which, when adjusting the output level of the laser light, makes the scanner 4 temporarily scan a range that includes the outside of a prescribed scanning area, causes the characteristic detection laser light to be output when a region outside the prescribed scanning area is being scanned, and adjusts the output level of the laser light on the basis of a detection result of the output level of the characteristic detection laser light.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an image display device and an image display method.

  As this type of technology, Patent Document 1 discloses a laser projector that displays a desired image on a screen by two-dimensionally scanning laser light output from a semiconductor laser. In general, the I-L characteristic, which is the relationship between the drive current of a laser light source such as a semiconductor laser and the amount of output light, easily changes due to temperature fluctuations of the laser light source itself. Therefore, in Patent Document 1, temperature fluctuation of the laser light source itself is suppressed by appropriately adjusting the drive current of the laser light source while the laser light is shielded by the shielding plate.

JP 2013-164503 A

  By the way, the applicant of the present application outputs laser light from a laser light source on a trial basis, acquires an IL characteristic by measuring the output light amount of the laser light with a photodiode, and drives the laser light source based on the acquired IL characteristic. We are developing APC technology (Auto Power Control) that adjusts the current periodically. In the APC technique, the laser beam output on a trial basis is shielded by using a shielding plate or the like, as in Patent Document 1, so that the laser beam output on a trial basis does not reach the screen.

  Here, the image drawing area and the blanking area will be described. The aforementioned two-dimensional scanning area (hereinafter referred to as scanning area) is divided into an image drawing area and a blanking area. The image drawing area is a rectangular area in which an image to be displayed on the screen is actually drawn. The blanking area is a frame-shaped dark area surrounding the image drawing area.

  In developing the APC technology, the most problematic issue is the arrangement of the shielding plate.

  At first glance, it seems that a shielding plate is arranged in the blanking region and a test laser beam is outputted from the laser light source at the timing of scanning the shielding plate. However, it is not realistic to arrange the shielding plate in the blanking region. This is because advanced positioning is required at the manufacturing stage so that the shielding plate does not overlap with the image drawing area. Even if the shielding plate does not overlap with the image drawing area, the shielding plate is shielded afterwards due to factors over time. This is because it is considered that the board overlaps the image drawing area.

  On the other hand, there is also an idea that if the scanning area itself is enlarged to secure a large blanking area, the shielding plate can be arranged away from the image drawing area. However, in this case, since the ratio of the time for scanning the image drawing area to the time for scanning the entire scanning area is lowered, the luminance of the image displayed in the image drawing area is lowered.

  Accordingly, an object of the present invention is to provide a technique for detecting the I-L characteristic of a laser light source without any problem.

  Therefore, the present invention provides a laser light source unit that outputs laser light, a scanner unit that reflects and scans laser light output from the laser light source unit, and the scanner unit scans laser light with a predetermined amplitude. A scanner control unit that controls scanning of the scanner unit, and a drawing image based on input image data is generated by scanning of the scanner unit in a predetermined scanning region scanned by the scanner unit. A laser light source control unit that controls the laser light output timing and the output value of the laser light, and controls the laser light source unit to output a characteristic detection laser beam for detecting the output value of the laser light output from the laser light source unit. When the output value of the laser beam output from the laser light source unit is adjusted, the scanner unit temporarily scans outside the predetermined scanning region. And controlling the scanner control unit to control the laser light source control unit so as to output the characteristic detection laser beam while scanning outside the predetermined scanning region, and the characteristic detection laser beam. And a characteristic detection control unit that adjusts the output value of the laser beam based on the detection result of the output value of the laser beam.

  The present invention also relates to an image drawing method for generating a drawn image in a predetermined scanning region by reflecting a laser beam output from a laser light source unit to a scanner unit that scans at a predetermined amplitude. When adjusting the output value of the laser beam, the scanning of the scanner unit temporarily scans a range including the outside of the predetermined scanning region, and the laser beam is scanned while scanning the outside of the predetermined scanning region. Provided is an image drawing method for outputting characteristic detection laser light for detecting an output value and adjusting the output value of the laser light based on the detection result of the output value of the characteristic detection laser light.

  ADVANTAGE OF THE INVENTION According to this invention, the drawing quality fall of the drawing image by irradiation of the laser beam for detecting the output value of a laser beam can be suppressed.

It is a functional block diagram of an image drawing apparatus. (First embodiment) It is a figure which shows the example of input image data. (First embodiment) It is a figure which shows the example of laser drive data typically. (First embodiment) It is a graph which shows typically a time change of a vertical scanning angle and a horizontal scanning angle. (First embodiment) It is a figure which shows the locus | trajectory of scanning typically. (First embodiment) It is a flowchart which shows the example of control of an image drawing apparatus. (First embodiment) It is a graph which shows typically a time change of a vertical scanning angle and a horizontal scanning angle. (First embodiment) It is a figure which shows the locus | trajectory of scanning typically. (First embodiment) It is a graph which shows typically a time change of a vertical scanning angle and a horizontal scanning angle. (Second Embodiment) It is the A section enlarged view of FIG. (Second Embodiment) It is a figure which shows the locus | trajectory of scanning typically. (Second Embodiment) It is a graph which shows typically a time change of a vertical scanning angle and a horizontal scanning angle. (Third embodiment) It is the B section enlarged view of FIG. (Third embodiment) It is a figure which shows the locus | trajectory of scanning typically. (Third embodiment)

(First embodiment)
The first embodiment will be described below with reference to the drawings. FIG. 1 shows a functional block diagram of the image drawing apparatus 1 of the first embodiment. The image drawing device 1 is specifically a head-up display device, which is mainly mounted on a vehicle and presents various information as virtual images to a driver who is a user. When the image drawing device 1 is used as a head-up display device, an image intended for route guidance, an image intended for warning, an image based on content reproduction, and an image related to various UIs (User Interfaces) Are presented as virtual images based on the drawn images. These images may be still images or moving images.

  The image drawing apparatus 1 includes a control unit 2, a laser light source unit 3, a scanner unit 4, a DDR memory 5 (Double Data Rate), and a shielding plate 9 as a shielding unit.

  The control unit 2 includes a central processing unit (CPU) (not shown), a read / write free RAM (Random Access Memory), a read-only ROM (Read Only Memory), and the like. Then, when the CPU reads and executes the image drawing program stored in the ROM, the image drawing program uses the hardware such as the CPU as the laser light source control unit 6, the scanner control unit 7, and the characteristic detection control unit 8. Make it work.

  The laser light source unit 3 includes a laser module 10 that outputs laser light, and a laser driver 11 that drives a laser diode 101 provided in the laser module 10. In this embodiment, the laser module 10 includes a red laser diode 101R, a green laser diode 101G, a blue laser diode 101B, a dichroic mirror 102 corresponding to each laser diode 101, and a photodiode 14. The laser beams of the respective colors output from the laser diodes 101 included in the laser module 10 are combined by the dichroic mirror 102 and output to the scanner unit 4. The laser driver 11 drives the laser diode 101 included in the laser module 10 based on the laser drive signal from the control unit 2.

  The dichroic mirror 102R has a characteristic of reflecting almost 100% of the red wavelength light output from the red laser diode 101R. The dichroic mirror 102G has a characteristic of transmitting approximately 100% of the red wavelength light output from the red laser diode 101R and reflecting approximately 100% of the green wavelength light output from the green laser diode 101G. The dichroic mirror 102B has a characteristic of reflecting about 98% and transmitting about 2% of the red wavelength light output from the red laser diode 101R and the green wavelength light output from the green laser diode 101G. Further, the dichroic mirror 102B has a characteristic of transmitting about 98% of the blue wavelength light output from the blue laser diode 101B and reflecting about 2%.

  With the configuration of the dichroic mirror 102 as described above, approximately 98% of the laser light output from each laser diode 101 is reflected by the scanner unit 12 and approximately 2% of the laser light is incident on the photodiode 14. . The photodiode 14 measures the light amount of each laser beam incident as a light amount measuring unit, and outputs the measurement result to the control unit 2. The arrangement of the laser diode 101 and the dichroic mirror 102 is not limited to the arrangement shown in FIG. 1, and the same output may be provided to the scanner unit 4 and the photodiode 14.

  The scanner unit 4 includes a scanner 12 that reflects and scans the laser light output from the laser light source unit 3, a scanner driver 13 that drives the scanner 12, and scanning as a scanning angle detection unit that detects the scanning angle of the scanner 12. And a corner detection unit 15. The scanner 12 includes a vertical mirror 12a that scans laser light in the vertical direction (first scanning direction) and a horizontal mirror 12b that scans laser light in the horizontal direction (second scanning direction). Both the vertical mirror 12a and the horizontal mirror 12b are constituted by MEMS (micro electro mechanical system) mirrors. The scanner driver 13 drives the scanner 12 based on the scanner drive signal from the control unit 2. The scanning angle detector 15 detects the scanning angles of the vertical mirror 12 a and the horizontal mirror 12 b and outputs the detection result to the controller 2.

  When the scanner 12 is composed of a vertical mirror 12a and a horizontal mirror 12b, the vertical mirror 12a operates at a scanning angle and an oscillation frequency that are generally controlled by the scanner driver 13. Since the horizontal mirror 12b has a high oscillation frequency, the horizontal mirror 12b generally operates at a scanning angle and an oscillation frequency due to resonance. However, the horizontal mirror 12b also has a scanning angle and oscillation controlled by the scanner driver 13 like the vertical mirror 12a. It may be configured to operate at a frequency.

  Based on the input image data input to the control unit 2, a laser beam output from the laser light source unit 3 is scanned by the scanner unit 4, thereby generating a drawn image. In the example of FIG. 1, the laser beam scanned by the scanner unit 4 is projected on the screen 16. The screen 16 is generally an intermediate image screen when the image drawing device 1 is used as a head-up display device. Although the structure of the head-up display is not shown, the drawn image projected on the intermediate image screen is projected on a combiner or a windshield of an automobile through reflection by a concave mirror or the like.

  The DDR memory 5 is a frame buffer that temporarily stores input image data input to the control unit 2.

  The shielding plate 9 is a plate that shields laser light. The laser beam shielded by the shielding plate 9 does not reach the projection direction beyond the screen 16. The shielding plate 9 has a shape that shields the characteristic detection laser light without shielding the laser light in the range where the drawn image is drawn out of the laser light reflected by the scanner unit 4. The shielding plate 9 is formed using a housing of the image drawing apparatus 1 or a housing of a unit including the scanner unit 4 and the laser light source unit 3. Further, when the scanner unit 4 is installed as a module in the image drawing apparatus 1, the shielding plate 9 is installed at a position where laser light is emitted from the module, or from the housing of the image drawing apparatus 1 to the screen 16. The position where the laser beam is emitted may be at the front portion or the rear portion of the screen 16.

  The laser light source control unit 6 is a functional unit that controls the output of the laser diode 10 by outputting a laser drive signal to the laser driver 11. The laser light source controller 6 has a laser drive signal frame buffer 6a. The laser light source control unit 6 reads input image data for one frame from the DDR memory 5, and stores the read input image data as it is in the laser drive signal frame buffer 6a as laser drive data. FIG. 2 shows a drawing image example for one frame of input image data. For convenience of explanation, it is assumed that the pixel size of the input image data is n rows and m columns, and the image of the input image data has a red circle drawn at the center. FIG. 3 shows laser drive data. The laser drive data is configured to generate an image of one frame having a pixel size of n rows and m columns in synchronization with the scanning of the scanner unit 4. As shown in FIGS. 2 and 3, the laser drive data is usually exactly the same data as the input image data. The laser light source controller 6 sequentially outputs the laser drive data stored in the laser drive signal frame buffer 6a to the laser driver 11 as a laser drive signal according to the dot clock. Therefore, the laser light source control unit 6 controls the output timing of the laser light so that a drawn image based on the input image data is generated by scanning of the scanner unit 4 within the scanning range scanned by the scanner unit 4. Further, the laser light source control unit 6 controls driving of the red, blue, and green laser diodes so as to obtain appropriate output values according to the color and luminance of the drawn image based on the input image data.

  The scanner control unit 7 is a functional unit that controls scanning of laser light by the scanner 12 by outputting a scanner drive signal to the scanner driver 13. FIG. 4 shows an example of the vertical scanning angle a of the vertical mirror 12a and the horizontal scanning angle b of the horizontal mirror 12b. As shown in FIG. 4, the vertical scanning angle a is represented by a triangular wave, and the horizontal scanning angle b is represented by a sine wave. The amplitude and scanning center of the vertical scanning angle a are constant, and the amplitude and scanning center of the horizontal scanning angle b are also constant. The scanning frequency of the vertical mirror 12a is 60 Hz, for example. The scanning frequency of the horizontal mirror 12b is higher than the scanning frequency of the vertical mirror 12a, for example, 15 kHz. In this specification, for convenience of explanation, the scanning frequency of the horizontal mirror 12b is set to 12 times the scanning frequency of the vertical mirror 12a. FIG. 5 shows a state in which the image drawing apparatus 1 draws an image on the screen 16 based on the input image data. In FIG. 5, a thin solid line indicates the locus of the scanning position of the scanner 12. As shown in FIG. 5, the locus of the scanning position of the scanner 12 is within a rectangular frame. An area within the rectangular frame is referred to as a scanning area SA. The horizontal width SAH of the scanning area SA corresponds to the amplitude HA of the horizontal scanning angle b in FIG. Similarly, the vertical width SAV of the scanning area SA in FIG. 5 corresponds to the amplitude VA of the vertical scanning angle a in FIG. The scanning area SA is divided into an image drawing area DA and a blanking area BA. The image drawing area DA is an area inside the scanning area SA, and is a rectangular area where an image is actually drawn. The blanking area BA is an area of a rectangular frame surrounding the image drawing area DA, and is an area where a laser beam for drawing a drawn image is not output. The blanking area BA further includes an upper blanking area BAU, a lower blanking area BAD, a left blanking area BAL, and a right blanking area BAR. The upper blanking area BAU is an area above the image drawing area DA in the blanking area BA. The horizontal width of the upper blanking area BAU is equal to the horizontal width SAH. The lower blanking area BAD is an area below the image drawing area DA in the blanking area BA. The horizontal width of the lower blanking area BAD is equal to the horizontal width SAH. The left blanking area BAL is an area on the left side of the image drawing area DA in the blanking area BA. The vertical width of the left blanking area BAL is equal to the vertical width SAV. The right blanking area BAR is an area on the right side of the image drawing area DA in the blanking area BA. The vertical width of the right blanking area BAR is equal to the vertical width SAV. The upper blanking area BAU partially overlaps the left blanking area BAL and the right blanking area BAR. The lower blanking area BAD partially overlaps the left blanking area BAL and the right blanking area BAR. Hereinafter, the scanning of the scanner 12 will be described in detail with reference to FIGS. 4 and 5.

  As shown in FIG. 4, in the vertical scanning, the upper blanking area scanning period P1 in which the scanning position moves downward in the upper blanking area BAU in order on the time axis, and the scanning position is the upper blanking area BAU and the lower blanking. Image drawing area scanning period P2 that moves downward between areas BAD, lower blanking area scanning period P3 in which the scanning position moves downward in the lower blanking area BAD, vertical return in which the scanning position moves upward in the scanning area SA This is achieved by repeating the scanning period P4. The image of the input image data is drawn on the screen 16 in the image drawing area scanning period P2, and in the period of the lower blanking area scanning period P3, the vertical return scanning period P4, and the upper blanking area scanning period P1 which are continuous on the time axis. Nothing is drawn on the screen 16. Hereinafter, the image drawing area scanning period P2 is referred to as an image drawing period Q1 as a period for drawing an image. A period constituted by the lower blanking area scanning period P3, the vertical return scanning period P4, and the upper blanking area scanning period P1 that are continuous on the time axis is referred to as a non-image drawing period Q2 as a period during which no image is drawn. Accordingly, the vertical scanning is realized by repeating the image drawing period Q1 and the non-image drawing period Q2 on the time axis. A period constituted by one vertical return scanning period P4, one upper blanking area scanning period P1, one image drawing area scanning period P2, and one lower blanking area scanning period P3 which are continuous on the time axis. This is called a frame period F as a period for one frame. Therefore, vertical scanning is realized by repeating the frame period F on the time axis.

  The vertical scanning angle a at the scanning center of the vertical scanning is defined as the vertical scanning angle center a0, the vertical scanning angle a at the time of folding up the vertical scanning is set as the folding up scanning angle a1, and the vertical scanning angle at the folding down of the vertical scanning Let a be the downward folding scanning angle a2. Similarly, the horizontal scanning angle b at the scanning center of the horizontal scanning is set as the horizontal scanning angle center b0, the horizontal scanning angle b at the right side of the horizontal scanning is set as the right folding scanning angle b1, and the horizontal at the left side of the horizontal scanning is turned up. The scanning angle b is referred to as a left folded scanning angle b2.

  The characteristic detection control unit 8 is a functional unit that periodically detects whether an appropriate output light amount is obtained with respect to a predetermined drive current applied to the laser diode 101. For example, the laser diode 101 may not be able to obtain a light amount based on the rated value of the I-L characteristic due to a decrease in ambient temperature. In this case, the color tone of the generated drawn image changes due to different characteristics of the red, blue, and green laser diodes 101. In FIG. 1, the characteristic detection control unit 8 outputs the characteristic detection laser beam to each of the red, blue, and green laser diodes 101 constituting the laser diode 101, and measures the light amount of the characteristic detection laser beam from the photodiode 14. Based on the measurement result, the drive current of the laser driver 11 is controlled so that each laser diode 101 outputs an appropriate amount of light. Such processing is hereinafter referred to as APC (Auto Power Control) processing. The characteristic detection laser beam is a test laser beam for detecting the output value of the laser beam output from each laser diode 101. The characteristic detection control unit 8 optimizes the control of the laser driver 11 by the laser light source control unit 6 by feeding back the detected output value to the laser light source control unit 6. The frequency with which the characteristic detection control unit 8 executes the APC process is, for example, about once per 120 frames.

  Further, when performing the APC process, the characteristic detection control unit 8 controls the scanner control unit 7 so that the scanning of the scanner 12 is temporarily scanned outside the predetermined scanning region. The predetermined scanning area is the scanning area SA. It is appropriate to execute the APC process by the characteristic detection processing unit 8 during a period of one frame of the drawn image. Furthermore, when performing the APC process, the characteristic detection control unit 8 controls the laser light source control unit 6 so that the characteristic detection laser beam is output while scanning outside the predetermined scanning region.

  Hereinafter, for convenience of explanation, the non-image drawing period Q2 in which the APC process is performed by the characteristic detection control unit 8 among the plurality of non-image drawing periods Q2 is specifically referred to as a characteristic detection non-image drawing period Q2IL.

  Hereinafter, the APC processing by the characteristic detection control unit 8 among the operations of the image drawing apparatus 1 will be described in detail.

  FIG. 6 shows a control flow of the image drawing apparatus 1, and FIG. 7 shows a graph showing temporal changes in the vertical scanning angle and the horizontal scanning angle. Here, as shown in FIG. 7, it is assumed that the first non-image drawing period Q2 appearing on the time axis is a characteristic detection non-image drawing period Q2IL.

  The characteristic detection control unit 8 first determines whether or not the next non-image drawing period Q2 is the characteristic detection non-image drawing period Q2IL (S300). When it is determined that the next non-image drawing period Q2 is not the characteristic detection non-image drawing period Q2IL (S300: NO), the characteristic detection control unit 8 repeats the above determination. When it is determined that the next non-image drawing period Q2 is the characteristic detection non-image drawing period Q2IL (S300: YES), the characteristic detection control unit 8 performs characteristic detection non-image drawing as shown in FIGS. In the period Q2IL, the scanner 12 is instructed to scan the outside of the scanning area SA which is a predetermined scanning area (S310). In the present embodiment, the scanner control unit 7 controls the scanning of the scanner 12 so that the scanner 12 scans the right side of the scanning area SA in the characteristic detection non-image drawing period Q2IL. The right side of the scanning area SA here is the right side of the upper blanking area BAU. Specifically, the horizontal scanning right folding scanning angle b3 in the characteristic detection non-image drawing period Q2IL is set to be larger than the horizontal scanning right folding scanning angle b1 in the other non-image drawing period Q2, and the characteristic detection non-characteristic is performed. The horizontal scanning left folding scanning angle in the image drawing period Q2IL is set to be equal to the horizontal scanning left folding scanning angle b2 in the other non-image drawing period Q2. On the other hand, the scanner control unit 7 keeps the vertical scanning in the characteristic detection non-image drawing period Q2IL as the vertical scanning in the other non-image drawing period Q2.

  Next, the characteristic detection control unit 8 instructs the laser light source control unit 6 to output the characteristic detection laser light from the laser module 10 in the characteristic detection non-image drawing period Q2IL (S320). FIG. 7 shows the timing at which the characteristic detection laser beam is output. The characteristic detection laser light is output from each of the red, blue, and green laser diodes 101 for each characteristic detection non-image drawing period, and the photodiode 14 measures the output light amount of each laser diode 101. In FIG. 8, the area where the characteristic detection laser light is projected is indicated by a thick line so as to overlap the scanning locus. As shown in FIGS. 7 and 8, the laser light source control unit 6 is configured so that each laser diode outputs a characteristic detection laser beam from the laser module 10 while the scanner 12 scans the outside of the scanning area SA. 101 is controlled. Specifically, the laser light source controller 6 outputs each laser diode 101 so that the characteristic detection laser light is output from the laser module 10 while the scanner 12 scans the right side of the upper blanking area BAU. To control. The shielding plate 9 shown in FIG. 1 is arranged at a position that shields the characteristic detection laser beam output from the laser diode 10 while the scanner 12 scans the outside of the scanning area SA. According to the above processing, the position at which the characteristic detection laser beam is projected can be separated from the position of the drawing image without changing the position of the drawing image or the drawing position. For this reason, it can reduce that the stray light by the irregular reflection of the characteristic detection laser beam shielded by the shielding plate 9 is reflected in the drawn image region, and can suppress the deterioration of the quality of the drawn image.

  Next, the characteristic detection control unit 8 acquires a measurement result from the photodiode 14 that has measured the light amount of the characteristic detection laser beam (S330), and based on the acquired measurement result, an actual output value of each laser diode 101. (S340), and the laser light source control unit 6 is controlled so that each laser diode 101 outputs an appropriate amount of light based on the detection result.

  Although the first embodiment has been described above, the first embodiment can be modified as follows.

  In the first embodiment, as shown in FIGS. 7 and 8, in the characteristic detection non-image drawing period Q2IL, the scanner 12 scans the area outside the predetermined scanning area on the right side of the upper blanking area BAU. However, instead, in the characteristic detection non-image drawing period Q2IL, the scanner 12 may scan an area outside the predetermined scanning area on the left side of the upper blanking area BAU, or on the right side of the lower blanking area BAD or The area outside the predetermined scanning area may be scanned on the left side. In any case, during the characteristic detection non-image drawing period Q2IL, the scanner 12 scans outside the scanning area SA, and the characteristic detection laser beam is emitted from the laser module while the scanner 12 scans outside the scanning area SA. The points output from 10 are common.

  The timing of outputting the characteristic detection laser beam may be any timing as long as the scanner 12 is scanning the outside of the scanning area SA. For example, the timing may be within the vertical return scanning period P4, or may be within the upper blanking area scanning period P1 or the lower blanking area scanning period P3.

(Second Embodiment)
Next, a second embodiment will be described. Hereinafter, the present embodiment will be described with a focus on differences from the first embodiment, and overlapping description will be omitted.

  In the first embodiment, the characteristic detection control unit 8 causes the scanner 12 to scan the area on the right side of the scanning area SA in the characteristic detection non-image drawing period Q2IL. On the other hand, in the present embodiment, as shown in FIGS. 9 and 11, the scanner 12 scans the area above the scanning area SA in the IL characteristic detection non-image drawing period Q2IL.

  That is, the characteristic detection control unit 8 first determines whether the next non-image drawing period Q2 is the characteristic detection non-image drawing period Q2IL (S300). When it is determined that the next non-image drawing period Q2 is not the characteristic detection non-image drawing period Q2IL (S300: NO), the characteristic detection control unit 8 repeats the above determination. When it is determined that the next non-image drawing period Q2 is the characteristic detection non-image drawing period Q2IL (S300: YES), the characteristic detection control unit 8 performs characteristic detection non-image drawing as shown in FIGS. In the period Q2IL, the scanner 12 is instructed to scan the outside of the scanning area SA which is a predetermined operation area (S310). In the present embodiment, the scanner control unit 7 controls the scanning of the scanner 12 so that the scanner 12 scans the upper side of the scanning area SA in the characteristic detection non-image drawing period Q2IL. Specifically, the vertical scanning upward folding angle a3 in the characteristic detection non-image drawing period Q2IL is set to be larger than the vertical scanning upward folding scan angle a1 in the other non-image rendering period Q2, and the characteristic detection non- The downward folding scanning angle in the vertical scanning in the image drawing period Q2IL is set to be equal to the downward folding scanning angle a2 in the vertical scanning in the other non-image rendering period Q2. On the other hand, the scanner control unit 7 keeps the horizontal scanning in the characteristic detection non-image drawing period Q2IL as the horizontal scanning in the other non-image drawing period Q2. In the present embodiment, as shown in FIG. 10, the vertical scanning angle a changes linearly in the upper blanking region scanning period P1 of the characteristic detection non-image drawing period Q2IL. Accordingly, as shown in FIG. 11, the trajectory of the scanning position of the scanner 12 extends entirely in the vertical direction in the area above the image drawing area DA.

  Next, the characteristic detection control unit 8 instructs the laser light source control unit 6 to output the characteristic detection laser light from the laser module 10 in the characteristic detection non-image drawing period Q2IL (S320). FIG. 9 shows the timing at which the characteristic detection laser beam is output. The characteristic detection laser light is output from each of the red, blue, and green laser diodes 101 for each characteristic detection non-image drawing period, and the photodiode 14 measures the output light amount of each laser diode 101. In FIG. 11, the area where the characteristic detection laser beam is projected is indicated by a thick line so as to overlap the scanning locus. As shown in FIGS. 9 and 11, the laser light source control unit 6 is configured so that each laser diode outputs a characteristic detection laser beam from the laser module 10 while the scanner 12 scans the outside of the scanning area SA. 101 is controlled. Specifically, the laser light source control unit 6 outputs each laser diode 101 so that the characteristic detection laser light is output from the laser module 10 while the scanner 12 scans the upper blanking area BAU. To control. The shielding plate 9 shown in FIG. 1 is disposed at a position that shields the characteristic detection laser beam output from the laser module 10 while the scanner 12 scans the outside of the scanning area SA. According to the above processing, the position at which the characteristic detection laser beam is projected can be separated from the position of the drawing image without changing the shape or drawing position of the drawing image. For this reason, it can reduce that the stray light by the irregular reflection of the characteristic detection laser beam shielded by the shielding plate 9 is reflected in the drawn image region, and can suppress the deterioration of the quality of the drawn image.

  Next, the characteristic detection control unit 8 acquires a measurement result from the photodiode 14 that has measured the light amount of the characteristic detection laser beam (S330), and based on the acquired measurement result, an actual output value of each laser diode 101. (S340), and based on the detection result, the laser light source controller 6 is controlled so that the laser diode 101 of each laser outputs an appropriate amount of light.

  Although the second embodiment has been described above, the second embodiment can be modified as follows.

  In the first embodiment, as shown in FIGS. 9 and 11, in the characteristic detection non-image drawing period Q2IL, the scanner 12 scans an area outside the predetermined scanning area above the upper blanking area BAU. However, instead of this, in the characteristic detection non-image drawing period Q2IL, the scanner 12 may scan the area outside the predetermined scanning area below the lower blanking area BAD, or the upper side of the upper blanking area BAU. In addition, the area outside the predetermined scanning area may be scanned on each of the lower sides of the lower blanking area BAD. In any case, during the characteristic detection non-image drawing period Q2IL, the scanner 12 scans outside the scanning area SA, and the characteristic detection laser beam is emitted from the laser module while the scanner 12 scans outside the scanning area SA. The points output from 10 are common.

  The timing of outputting the characteristic detection laser beam may be any timing as long as the scanner 12 is scanning the outside of the scanning area SA. For example, the timing may be within the vertical return scanning period P4, or may be within the upper blanking area scanning period P1 or the lower blanking area scanning period P3.

(Third embodiment)
Next, a third embodiment will be described. Hereinafter, the present embodiment will be described with a focus on differences from the second embodiment, and a duplicate description will be omitted.

  In the second embodiment, as shown in FIG. 10, as shown in FIG. 10, the vertical scanning angle a changes linearly in the upper blanking region scanning period P1 of the characteristic detection non-image drawing period Q2IL. . On the other hand, in the present embodiment, as shown in FIGS. 12 and 13, the vertical scanning angle a changes in a step shape in the upper blanking region scanning period P1 of the characteristic detection non-image drawing period Q2IL. Accordingly, as shown in FIG. 14, the portion above the image drawing area DA in the trajectory of the scanning position of the scanner 12 moves as it is without changing its shape further upward.

  Although the third embodiment has been described above, the third embodiment can be modified as follows.

  In the third embodiment, as shown in FIGS. 12 and 14, in the characteristic detection non-image drawing period Q2IL, the scanner 12 scans the area outside the predetermined scanning area above the upper blanking area BAU. However, instead of this, in the characteristic detection non-image drawing period Q2IL, the scanner 12 may scan the area outside the predetermined scanning area below the lower blanking area BAD, or the upper side of the upper blanking area BAU. In addition, the area outside the predetermined scanning area may be scanned on each of the lower sides of the lower blanking area BAD. In any case, during the characteristic detection non-image drawing period Q2IL, the scanner 12 scans outside the scanning area SA, and the characteristic detection laser beam is emitted from the laser module while the scanner 12 scans outside the scanning area SA. The points output from 10 are common.

  The timing of outputting the characteristic detection laser beam may be any timing as long as the scanner 12 is scanning the outside of the scanning area SA. For example, the timing may be within the vertical return scanning period P4, or may be within the upper blanking area scanning period P1 or the lower blanking area scanning period P3.

  Although the first embodiment, the second embodiment, and the third embodiment have been described above, each of the above embodiments has the following features.

(1) The image drawing apparatus 1 includes a laser light source unit 3 that outputs laser light, a scanner unit 4 that reflects and scans the laser light output from the laser light source unit 3, and the scanner unit 4 outputs laser light with a predetermined amplitude. The scanner control unit 7 that controls the scanning of the scanner unit 4 and the drawn image based on the input image data are generated by the scanning of the scanner unit 4 in a predetermined scanning area that the scanner unit 4 scans. Control for controlling the laser light output timing of the laser light source unit 3 and the output value of the laser light, and causing the laser light source unit 3 to output the characteristic detection laser light for detecting the output value of the laser light output from the laser light source unit 4 When adjusting the output value of the laser light source output from the laser light source control unit 6 and the laser light source unit 3, the scanning of the scanner unit 4 is temporarily scanned outside the predetermined scanning region. The laser light source control unit 6 is controlled so as to output the characteristic detection laser beam while scanning the outside of the predetermined scanning region while controlling the canner control unit 7, and the output value of the laser beam by the characteristic detection laser beam And a characteristic detection control unit 8 that adjusts the output value of the laser beam based on the detection result. The scanning frequency in the vertical direction is lower than the scanning frequency in the horizontal direction. In vertical scanning, an image drawing period Q1, which is a period for drawing an image, and a non-image drawing period Q2, which is a period for not drawing an image, are alternately repeated on the time axis. The characteristic detection control unit 8 controls the scanning of the scanner 12 so that the scanner 12 temporarily scans the outside of the scanning area SA in the characteristic detection non-image drawing period Q2IL in the non-image drawing period Q2. While scanning the outside of the scanning area SA, the output of each laser diode 101 is controlled so that the characteristic detection laser beam is output from the laser module 10, and the light quantity of each laser diode 101 is detected. According to the above configuration, it is possible to suppress a reduction in drawing quality of a drawn image due to irradiation with a characteristic detection laser beam output during APC processing.

  Further, according to the above configuration, image drawing can be executed as usual in the image drawing period Q1.

(2) In the second embodiment and the third embodiment, the characteristic detection control unit 8 controls the scanning of the scanner 12 so that the scanner 12 moves out of the scanning area SA in the vertical direction.

(3) In the first embodiment, the characteristic detection control unit 8 controls the scanning of the scanner 12 so that the scanner 12 moves out of the scanning area SA in the horizontal direction.

(4) In the image drawing method in which the laser light output from the laser light source unit 3 is reflected by the scanner unit 4 that scans with a predetermined amplitude to generate a drawn image in a predetermined scanning region, the laser output from the laser light source unit 3 When adjusting the light output value, the scanner unit 4 temporarily scans the range including the outside of the predetermined scanning area, and detects the laser light output value while scanning the outside of the predetermined scanning area. Characteristic detection laser light is output, and the output value of the laser light is adjusted based on the detection result of the output value of the characteristic detection laser light. According to the above method, it is possible to suppress a reduction in drawing quality of a drawn image due to irradiation with a characteristic detection laser beam output during APC processing.

  Further, according to the above method, image drawing can be executed as usual in the image drawing period Q1.

DESCRIPTION OF SYMBOLS 1 Image drawing apparatus 6 Laser light source control part 7 Scanner control part 8 Characteristic detection control part 9 Shielding plate 10 Laser module 12 Scanner 14 Photodiode

Claims (4)

A laser light source for outputting laser light;
A scanner unit that reflects and scans the laser beam output from the laser light source unit;
A scanner control unit that controls scanning of the scanner unit so that the scanner unit scans laser light with a predetermined amplitude;
The laser light output timing of the laser light source unit and the output value of the laser light are controlled so that a drawing image based on input image data is generated by scanning of the scanner unit within a predetermined scanning area scanned by the scanner unit, A laser light source controller for controlling the laser light source unit to output a characteristic detection laser beam for detecting an output value of the laser beam output from the laser light source unit;
When adjusting the output value of the laser beam output from the laser light source unit, the scanner control unit is controlled so that the scanning of the scanner unit temporarily scans outside the predetermined scanning region, and the predetermined scanning is performed. The laser light source control unit is controlled to output the characteristic detection laser beam while scanning outside the region, and laser beam output is performed based on the detection result of the output value of the laser beam by the characteristic detection laser beam. A characteristic detection control unit for adjusting a value;
An image drawing apparatus comprising: The scanner control unit scans the scanner unit so as to scan the scanner unit with a predetermined amplitude in a first scanning direction that is a vertical direction of the drawn image and a second scanning direction that is a horizontal direction of the drawn image. Control
The characteristic detection control unit temporarily scans the scanning in the first scanning direction in the scanner unit outside the predetermined scanning region when adjusting the output value of the laser beam output from the laser light source unit. To control the scanner control unit,
The image drawing apparatus according to claim 1. The scanner control unit scans the scanner unit so as to scan the scanner unit with a predetermined amplitude in a first scanning direction that is a vertical direction of the drawn image and a second scanning direction that is a horizontal direction of the drawn image. Control
The characteristic detection control unit temporarily scans the scanning unit in the second scanning direction outside the predetermined scanning region when adjusting the output value of the laser beam output from the laser light source unit. To control the scanner control unit,
The image drawing apparatus according to claim 1. An image drawing method in which a laser beam output from a laser light source unit is reflected by a scanner unit that scans with a predetermined amplitude to generate a drawing image in a predetermined scanning region,
When adjusting the output value of the laser beam output from the laser light source unit, the scanner unit temporarily scans a range including the outside of the predetermined scanning region,
Outputting a characteristic detection laser beam for detecting an output value of the laser beam when scanning outside the predetermined scanning region;
Adjusting the output value of the laser beam based on the detection result of the output value of the characteristic detection laser beam;
Image drawing method.

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