JP2009134135A - Rear projector and image projecting position adjustment method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rear projector, capable of automatically adjusting an image projecting position with high accuracy. <P>SOLUTION: The rear projector comprises a projector 6 for projecting an image constituted of a plurality of pixels on a screen 5 from the rear surface side thereof; optical sensor parts 4a-4d provided at four corners on a display screen of the screen 5; a 6-axial drive part 5 for making the projector 6 rotate and move; a pattern generator 2 for generating, in four corner areas of the image, a test pattern for successively lighting the pixels within the areas; and a control part 1 for controlling the 6-axial drive part 3, to adjust the image projected position of the projector 6. Each of the optical sensor parts 4a-4d includes a window of a size regulated by the size of the display screen and the resolution of the projector 6, and detects light through the window. The control part 1 acquires the positions of the optical sensor parts 4a-4d on the projected image, based on the lighting timings of pixels on the basis of the test pattern and the output values of the optical sensor parts 4a-4d. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a rear projector, and more particularly to a rear projector that can adjust the image projection position of the projector with respect to a screen.

  Patent Document 1 describes a rear projector having a projector provided with a six-axis adjustment mechanism capable of adjusting an image projection position with respect to a screen. The first axis adjustment mechanism is a mechanism that adjusts the rotation direction in the horizontal plane. The second axis adjustment mechanism is a mechanism that adjusts the rotation direction in a vertical plane orthogonal to the horizontal plane. The third axis adjusting mechanism is a mechanism for adjusting the rotation direction in a plane orthogonal to the horizontal plane and the vertical plane. The fourth axis adjustment mechanism is a mechanism that can move in the vertical direction. The fifth axis adjustment mechanism is a mechanism that can move in the left-right direction. The sixth axis adjustment mechanism is a mechanism that can move in the front-rear direction. The operator uses the first to sixth axis adjustment mechanisms to perform the adjustment work visually so that the projected image from the projector is projected to a predetermined position on the screen.

  Patent Document 2 describes a three-plate liquid crystal projector that is not a rear projector but has an automatic adjustment function. This three-plate type liquid crystal projector includes a liquid crystal panel for R (red), G (green), and B (blue), a color composition unit that performs color composition on image light from each liquid crystal panel, and a color composition unit that performs color synthesis. And a lens for projecting the synthesized image light onto the screen. Four position detectors are arranged at predetermined positions on the incident surface side of the lens. Each liquid crystal panel includes an adjustment mechanism capable of moving xyz in each direction and an adjustment mechanism capable of adjusting the rotation direction in a horizontal plane.

The three-plate liquid crystal projector has a control circuit that takes the output of each position detector as an input and controls the adjustment mechanism of each liquid crystal panel based on the input. For each of the liquid crystal panels, the control circuit turns on only one pixel at the four corners of the liquid crystal display screen portion so that light from the pixels at the four corners is incident on the center of the light receiving surfaces of the four position detectors Control each adjustment mechanism.
JP 2003-241308 A Japanese Patent Laid-Open No. 9-146062

  However, the rear projector described in Patent Document 1 requires manual adjustment work for each axis, which takes time for adjustment. In particular, when installing a multi-screen rear projector in which a plurality of rear projectors are connected, it is necessary to perform manual adjustment work for each rear projector, so that much time is spent for adjustment.

  Further, in the visual adjustment, since the adjustment accuracy is determined by the skill level of the worker, if the worker has little experience, it may not be possible to perform high-precision adjustment.

  According to the three-plate liquid crystal projector described in Patent Document 2, the projection position of the image from each liquid crystal panel can be automatically adjusted. However, this automatic adjustment mechanism is a convergence adjustment function, in which light from the pixels at the four corners of the liquid crystal display unit is respectively placed at the center of the light receiving surfaces of the four position detectors arranged on the incident surface side of the projection lens. The structure is adjusted so that it is incident. Therefore, it is difficult to apply this convergence adjustment function to image projection position adjustment in the rear projector.

  An object of the present invention is to provide a rear projector and an image projection position adjustment method that can solve the above-described problems.

In order to achieve the above object, a rear projector according to the present invention provides:
A projector that projects an image composed of a plurality of pixels onto a screen;
Four photosensors provided at the four corners on the display screen on the side opposite to the projector of the screen;
An axis drive unit comprising a plurality of axes intersecting with each other, and rotating and moving the projector around and in the direction of each axis;
A pattern generator for generating a test pattern for sequentially lighting pixels in the four corner areas of the image;
A control unit that performs a display operation by the projector and controls the driving unit to adjust an image projection position of the projector with respect to the screen;
Each of the four photosensor units includes a window having a size defined by a size of the display screen and a resolution indicating a density of pixels that can be displayed on the display screen by the projector, and the display through the window. Detect light from the screen,
The control unit causes the projector to project an image based on the test pattern generated by the pattern generator, the lighting timing of each pixel in the four corner regions of the projected image, and the four lighting timings of each pixel. The positions of the four photosensor units on the projection image are acquired based on the output values of the two photosensor units, and the range of the display screen obtained based on the positions matches the range of the projection image. And controlling the driving unit.

Moreover, the image projection position adjustment method of the present invention includes:
In the four corner areas of the image, generate a test pattern for sequentially lighting the pixels in the area,
Projecting an image based on the test pattern by the projector,
In the four photosensor units provided at the four corners on the display screen opposite to the projector on the screen, the size of the display screen and the density of pixels that the projector can display on the display screen are shown. Detecting light from the display screen through a window of a size defined by the resolution,
The projection images of the four photosensor units based on the lighting timing of each pixel in the four corner regions of the projection image based on the test pattern and the output values of the four photosensor units at the lighting timing of the pixels. Obtaining a position above, and rotating or moving the projector around or in a predetermined axis so that a range of the display screen obtained based on the position and a range of the projection image coincide with each other. It is characterized by.

  According to the present invention, since the axis adjustment (for example, 6-axis adjustment) can be automatically performed so that the range of the projected image and the range of the display screen of the screen coincide with each other, compared with a case where manual adjustment work is performed. Adjustment time can be shortened and the burden of installation work on the operator can be reduced.

  The optical sensor unit is configured to detect light from the display screen through a window having a size (specified pixel size) defined by the size of the display screen and the resolution of the projector. According to this configuration, the position of the optical sensor unit on the projection image can be calculated with an accuracy equal to or less than the prescribed pixel size, so that high-accuracy adjustment can be stably performed compared to the case where manual adjustment work is performed. Can be provided.

  Next, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing a configuration of a rear projector according to an embodiment of the present invention.

  Referring to FIG. 1, the rear projector includes a screen 5, a projector 6 having a six-axis drive unit 3, optical sensor units 4 a to 4 d provided at four corners of the screen 5, and a pattern for generating an adjustment image pattern. It has the generator 2, and the control part 1 which controls operation | movement of the 6-axis drive part 3 and the pattern generator 2. FIG.

  The projector 6 is an existing projector having a spatial light modulator that generates an image composed of a plurality of pixels, and a projection lens that projects the image generated by the spatial light modulator from the back side of the screen 5. The spatial light modulator is composed of a liquid crystal panel, DMD (Digital Micromirror Device), or the like. In the case of displaying a color image, three spatial light modulators for R, G, and B are used as the spatial light modulators, and the color synthesis unit changes the color of the image light from these spatial light modulators. Synthesize. The color-combined image light is projected by the projection lens.

  The six-axis drive unit 3 includes first to sixth axis adjustment mechanisms. 2A and 2B schematically show position adjustment by the first axis adjustment mechanism. The first axis adjustment mechanism is a mechanism that adjusts the rotation direction (around the y axis) in the horizontal plane (xz plane). In the first axis adjusting mechanism, as shown in FIG. 2A, the projector 6 is rotated in the rotation direction A1, or as shown in FIG. 2B, the projector 6 is rotated in the rotation direction A2 opposite to the rotation direction A1. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is rotated in the rotation direction A <b> 1, an image 10 having a smaller left portion and a larger right portion is projected onto the screen 5. On the contrary, when the projector 6 is rotated in the rotation direction A2, an image 10 having a smaller right side portion and a larger left side is projected onto the screen 5.

  3A and 3B schematically show position adjustment by the second axis adjustment mechanism. The second axis adjustment mechanism is a mechanism that adjusts the rotation direction (around the x axis) in a vertical plane (yz plane) orthogonal to the horizontal plane. In this second axis adjusting mechanism, the projector 6 is rotated in the rotation direction B1 as shown in FIG. 3A, or the projector 6 is rotated in the rotation direction B2 opposite to the rotation direction B1 as shown in FIG. 3B. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is rotated in the rotation direction B <b> 1, an image 10 whose upper portion is smaller and larger toward the lower side is projected onto the screen 5. On the other hand, when the projector 6 is rotated in the rotation direction B2, an image 10 having a smaller upper portion and a larger lower portion is projected onto the screen 5.

  4A and 4B schematically show position adjustment by the third axis adjustment mechanism. The third axis adjustment mechanism is a mechanism for adjusting the rotation direction (around the z axis) in a plane (xy plane) perpendicular to both the horizontal plane and the vertical plane. In the third axis adjusting mechanism, the projector 6 is rotated in the rotation direction C1 as shown in FIG. 3A, or the projector 6 is rotated in the rotation direction C2 opposite to the rotation direction C1 as shown in FIG. 3B. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is rotated in the rotation direction C1, the image 10 is rotated in the clockwise direction. On the other hand, when the projector 6 is rotated in the rotation direction C2, the image 10 is rotated counterclockwise.

  5A and 5B schematically show the position adjustment by the fourth axis adjustment mechanism. The fourth axis adjustment mechanism is a mechanism that moves in the vertical direction (z-axis direction). In the fourth axis adjusting mechanism, as shown in FIG. 5A, the projector 6 is moved in the downward direction D1, and as shown in FIG. 5B, the projector 6 is moved in the upward direction D2 opposite to the downward direction D1. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is moved in the downward direction D <b> 1, the screen 10 moves downward on the screen 5. On the other hand, when the projector 6 is moved in the upward direction D2, the screen 10 is moved upward on the screen 5.

  6A and 6B schematically show position adjustment by the fifth axis adjustment mechanism. The fifth axis adjustment mechanism is a mechanism that moves in the left-right direction (x-axis direction). In the fifth axis adjustment mechanism, the projector 6 is moved in the left direction E1 as shown in FIG. 6A, or the projector 6 is moved in the right direction E2 opposite to the left direction E1, as shown in FIG. 6B. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is moved in the left direction E <b> 1, the screen 10 is moved in the left direction on the screen 5. Conversely, when the projector 6 is moved in the right direction E2, the screen 10 is moved in the right direction on the screen 5.

  7A and 7B schematically show the position adjustment by the sixth axis adjustment mechanism. The sixth axis adjustment mechanism is a mechanism that moves in the front-rear direction (y-axis direction). In the sixth axis adjusting mechanism, as shown in FIG. 7A, the projector 6 is moved in the rear direction F1, and as shown in FIG. 7B, the projector 6 is moved in the front direction F2 opposite to the rear direction F1. You can make it.

  When viewed toward the back of the screen 5, when the projector 6 is moved in the rearward direction F1, the screen 10 on the screen 5 is enlarged. Conversely, when the projector 6 is moved in the forward direction F2, the screen 10 on the screen 5 is reduced.

  The optical sensor units 4a to 4d have the same configuration. FIG. 8 is an exploded perspective view of the optical sensor unit 4a. Referring to FIG. 8, the optical sensor unit 4 a includes a light shielding plate 41, an optical sensor 40, and a cover 42.

  The light shielding plate 41 is composed of a rectangular first to third plate member. The first to third plate members are joined so that their surfaces intersect each other at approximately 90 degrees. A window 41a having a predetermined size is provided at the center of the first plate member. Side portions of the second and third plate members are joined to two adjacent side portions of the first plate member. The light shielding plate 41 is fixed so that the surface of the first plate member is in close contact with the display surface of the screen 5, and each surface of the second and third plate members is in close contact with the adjacent side portions of the corners of the screen 5. Is done.

  FIG. 9 is a schematic view showing a state where the first plate member in which the window 41 a is formed is arranged on the screen 5. The size of the window 41a is determined by the size of the screen 5 (specifically, the display screen size) and the resolution indicating the density of pixels that can be displayed by the projector 6 (hereinafter referred to as the specified pixel). Equal to or approximately equal to the size). However, when the projector 6 can display at a plurality of different resolutions, it is desirable to use the maximum value among the resolutions as the resolution for defining the pixel size. By using the maximum resolution value, the detection accuracy of the position (coordinates) of the window 41a on the projection image can be further increased.

  The horizontal and vertical lengths W3 and W4 of the window 41a are equal to or substantially equal to the specified pixel size. The interval W1 between the vertical side portion of the window 41a and the vertical side portion of the first plate member is equal to or larger than the specified pixel size. An interval W2 between the side portion of the window 41a and the side portion of the first plate member is also equal to or larger than the specified pixel size. With this configuration, at least one column (or one row) of pixels can be arranged between the edge of the window 41a and the side of the screen. As a result, it is possible to realize a state in which the window 41a is arranged across four pixels, and the position of the photosensor can be calculated with high accuracy.

  Note that the window 41a is preferably in the same rectangular shape as the pixel shape of the display screen, but is not limited thereto. As long as the position (coordinates) of the window 41a on the projected image can be specified, the window 41a may have another shape such as a round shape. When the window 41a has a round shape, the length of the diameter is equal (or substantially equal) to the specified pixel size.

  As shown in FIG. 8, the optical sensor 40 is fixed to the light shielding plate 41 or the cover 42 so as to receive the light that has passed through the window 41a. The cover 42 is attached to the light shielding plate 41 so as to cover the surface of the first plate member. The optical sensor 40 is accommodated in a shielding space formed by the cover 42 and the first plate member. The output signal line of the optical sensor 40 is drawn out of the shielding space through a hole provided in a part of the cover 42. The output of the optical sensor 40 changes according to the intensity (light quantity) of light incident on the light receiving surface.

  The optical sensor units 4b to 4d have the same configuration as the optical sensor unit shown in FIGS.

  The pattern generator 2 generates an adjustment image pattern for adjusting the image projection position of the projector 6 with respect to the screen 5 in accordance with a control signal from the control unit 1. The adjustment image pattern is supplied to the projector 6. In the projector 6, an image based on the adjustment image pattern is formed on the image forming surface of the spatial light modulator. The adjustment image pattern includes pixels in each of the first pattern for simultaneously lighting all the pixels on the image forming surface of the spatial light modulator in the projector 6 and a region composed of a plurality of pixels located at the four corners of the image forming surface. And a second pattern for sequentially lighting in a predetermined order. The resolution of the image by the first and second patterns is the same as the maximum displayable resolution of the projector 6.

  The storage unit 7 stores information on a virtual image display area in which the coordinate values of each pixel on the image forming surface of the spatial light modulator in the projector 6 are developed on two-dimensional coordinates. When the projector 6 has a plurality of spatial light modulators, the virtual image display area is a pixel of an image (for example, a color composite image) obtained by spatially superimposing images generated by the spatial light modulators. The coordinate value is expanded on a two-dimensional coordinate. As described above, the virtual image display region means a coordinate value of each pixel of an image to be projected generated by the projector 6 developed on a two-dimensional coordinate.

  The control unit 1 controls the operations of the pattern generator 2 and the 6-axis drive unit 3 to perform image projection position adjustment processing. The image projection position adjustment process includes first and second image projection position adjustment processes.

  In the first image projection position adjustment process, the control unit 1 generates a first pattern with the pattern generator 2 and based on the first pattern with each of the optical sensors 40 of the optical sensor units 4a to 4d. At least one of the first to sixth axis adjustment mechanisms of the six-axis drive unit 3 is controlled so that the projection image light is received.

  In the second image projection position adjustment process, the control unit 1 causes the pattern generator 2 to generate the second pattern, and changes the output of each optical sensor 40 of the optical sensor units 4a to 4d and the second pattern. Based on the lighting timing of the pixel based on it, the coordinate which shows the position of each photosensor 40 on a virtual image display area is calculated | required. Then, the control unit 1 controls at least one of the first to sixth axis adjusting mechanisms of the six-axis driving unit 3 based on the obtained position coordinates of the respective optical sensors 40 to project the projection image from the projector 6. Is displayed at an appropriate position on the screen 5.

  Next, the operation of adjusting the image projection position performed by the rear projector of the present embodiment will be specifically described.

  In the image projection position adjustment, the control unit 1 first performs a first image projection position adjustment process, and then performs a second image projection position adjustment process.

(1) First image projection position adjustment processing:
FIG. 10 is a flowchart showing a procedure of the first image projection position adjustment process.

  Referring to FIG. 10, first, the control unit 1 causes the pattern generator 2 to generate a first pattern (step S10). The projector 6 projects image light based on the first pattern supplied from the pattern generator 2 from the back side of the screen 5. The image light projected on the screen 5 is in a state where all the pixels are lit.

  Next, the control unit 1 outputs image light projected from the projector 6 to the screen 5 based on output signals of the optical sensors 40 of the optical sensor units 4 a to 4 d provided on the display surface side of the screen 5. It is determined whether or not light is received by the sensor 40 (step S11).

  When each of the optical sensors 40 includes an optical sensor that does not receive projection image light, the control unit 1 controls at least one of the first to sixth axis adjustment mechanisms of the six-axis drive unit 3. Then, the position or size of the projected image on the screen 5 is adjusted (step S12). Thereafter, the determination in step S11 is performed. The processes in steps S11 and S12 are repeated until each optical sensor 40 receives the projection image light.

  If the size of the projected image is larger than the screen 5, each optical sensor 40 is in a state of receiving the projected image light. Therefore, in the axis adjustment in step S12, the projector 6 is moved in the forward direction using the sixth axis adjustment mechanism, and the projection image is enlarged, so that each optical sensor 40 can easily receive the projection image light. Obtainable.

(2) Second image projection position adjustment process:
FIG. 11 is a flowchart illustrating a procedure of the second image projection position adjustment process.

  Referring to FIG. 11, first, the control unit 1 causes the pattern generator 2 to generate a second pattern (step S100). The projector 6 projects image light based on the second pattern supplied from the pattern generator 2 from the back side of the screen 5.

  According to the second pattern, the pixels are sequentially lit in a predetermined order in each of the corner regions composed of a plurality of pixels located at the four corners of the image forming surface of the spatial light modulator in the projector 6. FIG. 12 schematically shows the lighting operation of the pixel in the corner region. In this example, the corner area is composed of pixels of 8 rows and 8 columns located at corners of the image forming surface 100. Lights in order from the pixel 101 located at the left end of the first row in order.

  In each corner area of the four corners of the image forming surface, a pixel lighting operation as shown in FIG. 12 is performed. Image light from each corner area is projected onto the screen 5 by the projection lens. In each of the optical sensor units 4 a to 4 d, only the light from the pixel where the window 41 a is located among the pixels of the projection image in the corner region reaches the optical sensor 40. Therefore, the output of the optical sensor 40 changes at the lighting timing of the pixel where the window 41a is located.

  FIG. 13 schematically shows the positional relationship between the projected image in the corner area and the window 41a. In this example, the window 41a is located in a region extending over the four pixels 101a to 101d among the pixels of the projection image in the corner region. The overlap between the pixel 101b and the window 41a is the largest. The overlap between the pixel 101d and the window 41a is the second largest, and the overlap between the pixel 101a and the window 41a is the third largest. The overlap between the pixel 101c and the window 41a is the smallest. When the pixels 101a to 101d are sequentially turned on, the light sensor 40 detects light of a light amount corresponding to the overlap difference.

  Note that the size of each pixel of the projection image in the corner area shown in FIG. 13 is larger than the prescribed pixel size. This is because the size of the projection image is set to the screen 5 by the first image projection position adjustment processing. This is because it is larger than the size.

  FIG. 14 is a schematic diagram when the optical sensor unit 4 a having the positional relationship shown in FIG. 13 is viewed from the display screen side of the screen 5. In FIG. 14, the optical sensor 40 and the cover 42 are omitted.

  As shown in FIG. 14, four pixels 101 a to 101 d in the projection image in the corner area are displayed on the display screen of the screen 5 in the area where the window 41 a is located. When the pixels 101a to 101d are sequentially turned on, the output of the optical sensor 40 changes.

  FIG. 15 shows the amount of light detected by the optical sensor 40 through the window 41a when the pixels 101a to 101d are sequentially turned on in the state shown in FIG. The vertical axis represents the amount of light, and the horizontal axis represents the pixel. The light quantity of the pixel 101a, the light quantity of the pixel 101b, the light quantity of the pixel 101c, and the light quantity of the pixel 101d are shown in order from the left. In FIG. 15, the dotted line indicates the amount of light when all the light from one pixel is received.

  The control unit 1 acquires the light amounts of the pixels 101a to 101d as illustrated in FIG. 15 from the output of the optical sensor 40 based on the lighting timing of each pixel in the second pattern. And the control part 1 calculates | requires the coordinate which shows the position of the optical sensor 40 on the virtual image display area stored in the memory | storage part 2 based on the ratio of each light quantity of the pixels 101a-101d. Here, the position coordinates of the optical sensor 40 are the coordinates of the central portion of the window 41a.

  The above-described pixel lighting control and optical sensor coordinate acquisition processing in step S100 are performed for each of the optical sensor units 4a to 4d.

  FIG. 16 shows the coordinates of each photosensor 40 on the virtual image display area. Due to the first image projection position adjustment processing, the size of the projection image is larger than the size of the screen 5, and each optical sensor 40 is positioned on the projection image. The coordinates of each optical sensor 40 are necessarily located on the virtual image display area 131. In FIG. 16, the coordinate H is the coordinate of the optical sensor 40 of the optical sensor unit 4c, the coordinate I is the coordinate of the optical sensor 40 of the optical sensor unit 4a, and the coordinate J is the coordinate of the optical sensor 40 of the optical sensor unit 4d. Yes, the coordinate K is the coordinate of the optical sensor 40 of the optical sensor unit 4b.

  Next, the control unit 1 determines whether or not the upper and lower ends of the projected image are parallel based on the coordinates of the optical sensors 40 of the optical sensor units 4a to 4d obtained in step S100 of FIG. S101).

  In the determination in step S <b> 101, the control unit 1 firstly relates the coordinates H, I, J, K of each photosensor 40 on the virtual image display area 131 and the position of each photosensor 40 on the display screen of the screen 5. Based on the above, the projection image range 142 for the frame 141 of the display screen of the screen 5 as shown in FIG. 17 is calculated. The control unit 1 obtains the coordinates P0, Q0, R0, and S0 of the pixels at the four corners of the projection image range 142. Then, the control unit 1 determines whether or not the upper side (upper end of the projection image) indicated by the straight line connecting the coordinates P0 and Q0 and the lower side (lower end of the projection image) indicated by the straight line connecting the coordinates R0 and S0 are parallel. Determine.

  If it is determined in step S101 that the upper and lower ends of the projected image are not parallel, the control unit 1 controls the first axis adjustment mechanism of the six-axis drive unit 3 to adjust the image projection position (step) S102). Then, the control part 1 performs the process of step S100, S101. The processes in steps S100 to S102 are repeated until the upper and lower ends of the projected image are parallel. FIG. 18 shows a projected image range 152 whose upper and lower ends are parallel. In FIG. 18, a frame 151 corresponds to the frame of the display screen of the screen 5.

  If it is determined in step S101 that the upper and lower ends of the projection image range 142 are parallel, the control unit 1 performs the process of step S103.

  In step S103, the control unit 1 obtains the coordinates P1, Q1, R1, and S1 of the pixels at the four corners of the projection image range 152 shown in FIG. Then, the control unit 1 determines whether or not the left side indicated by the straight line connecting the coordinates P1 and R1 (the left end of the projection image) and the right side indicated by the straight line connecting the coordinates Q1 and S1 (the right end of the projection image) are parallel. Determine.

  If it is determined in step S103 that the left and right ends of the projected image are not parallel, the control unit 1 controls the second axis adjustment mechanism of the six-axis drive unit 3 to adjust the image projection position (step). S104). Then, the control unit 1 causes the pattern generator 2 to generate the second pattern, specifies the coordinates of each photosensor 40 (step S105), and sets the projection image range 152 from the coordinates of each of the specified photosensors 40. calculate. Thereafter, the control unit 1 performs the determination process in step 103 again. Here, the process of step S105 is the same as the process of step S100. In the image projection position adjustment by the second axis adjustment mechanism, only the angle adjustment of the left and right ends of the projection image is performed, and the upper and lower ends of the projection image are maintained in a parallel state.

  The processes in steps S103 to S105 are repeated until the left and right edges of the projection image are parallel. FIG. 19 shows a projected image range 162 in which the left and right ends are parallel. In FIG. 19, a frame 161 corresponds to a display screen frame of the screen 5.

  If it is determined in step S103 that the left and right ends of the projected image range 142 are parallel, the control unit 1 performs the process of step S106.

  In step S106, the control unit 1 obtains the coordinates P2 and Q2 of the pixels at the two upper corners of the projected image range 162 shown in FIG. Then, the control unit 1 determines whether or not the upper side (the upper end of the projection image) indicated by a straight line connecting the coordinates P2 and Q2 is parallel to the upper side of the frame 161. In this determination processing, the control unit 1 obtains the coordinates R2 and S2 of the pixels at the two lower corners of the projected image range 162 shown in FIG. 19, and the lower side (projected image) indicated by a straight line connecting these coordinates R2 and S2. It may be determined whether or not the lower end of the frame 161 and the lower side of the frame 161 are parallel.

  If it is determined in step S106 that the upper end of the projection image and the upper side of the frame 161 of the screen 5 are not parallel, the control unit 1 controls the third axis adjustment mechanism of the six-axis drive unit 3 to control the image. The projection position is adjusted (step S107). Then, the control unit 1 causes the pattern generator 2 to generate the second pattern, specifies the coordinates of each photosensor 40 (step S108), and sets the projection image range 162 from the coordinates of each photosensor 40 thus specified. calculate. Thereafter, the control unit 1 performs the determination process of step 106 again. Here, the process of step S108 is the same as the process of step S100. In the image projection position adjustment by the third axis adjustment mechanism, only the rotation angle of the projection image with respect to the frame 161 is adjusted, and the upper and lower ends and the left and right ends of the projection image are maintained in a parallel state.

  The processes in steps S106 to S108 are repeated until the upper end of the projection image and the upper side of the frame 161 of the screen 5 are parallel to each other. FIG. 20 shows a projected image range 172 whose upper end is parallel to the upper side of the frame of the screen 5. In FIG. 20, a frame 171 corresponds to the frame of the display screen of the screen 5.

  If it is determined in step S106 that the upper end of the projected image and the upper side of the frame 161 of the screen 5 are parallel, the control unit 1 performs the process of step S109.

  In step S109, the control unit 1 obtains the coordinates P3, Q3, R3, and S3 of the pixels at the four corners of the projected image range 172 shown in FIG. Then, the control unit 1 determines that the distance between the upper side (upper end of the projection image) indicated by the straight line connecting the coordinates P3 and Q3 and the upper side of the frame 171 is the lower side (lower end of the projection image) indicated by the straight line connecting the coordinates R3 and S3. ) And the lower side of the frame 171.

  If it is determined in step S109 that the interval between the upper end of the projection image and the upper side of the frame 171 does not match the interval between the lower end of the projection image and the lower side of the frame 171, the control unit 1 performs the six-axis drive unit. The third fourth axis adjustment mechanism is controlled to adjust the image projection position (step S110). And the control part 1 produces | generates a 2nd pattern in the pattern generator 2, specifies the coordinate of each photosensor 40 (step S111), and sets the projection image range 172 from the coordinate of each specified photosensor 40. calculate. Thereafter, the control unit 1 performs the determination process of step 106 again. Here, the process of step S111 is the same as the process of step S100. In the image projection position adjustment by the fourth axis adjustment mechanism, only the vertical direction of the projection image with respect to the frame 171 is adjusted.

  The processes in steps S109 to S111 are repeatedly performed until the interval between the upper end of the projection image and the upper side of the frame 171 matches the interval between the lower end of the projection image and the lower side of the frame 171.

  If it is determined in step S109 that the interval between the upper end of the projection image and the upper side of the frame 171 matches the interval between the lower end of the projection image and the lower side of the frame 171, the control unit 1 performs the process of step S1112. Do.

  In step S112, the control unit 1 obtains the coordinates P3, Q3, R3, and S3 of the pixels at the four corners of the projected image range 172 shown in FIG. Then, the control unit 1 determines that the interval between the left side (the left end of the projection image) indicated by the straight line connecting the coordinates P3 and R3 and the left side of the frame 171 is the right side (the right end of the projection image) indicated by the straight line connecting the coordinates Q3 and S3. ) And the right side of the frame 171.

  If it is determined in step S112 that the interval between the left end of the projection image and the left side of the frame 171 does not match the interval between the right end of the projection image and the right side of the frame 171, the control unit 1 uses the six-axis drive unit. The third fifth axis adjustment mechanism is controlled to adjust the image projection position (step S113). And the control part 1 produces | generates a 2nd pattern in the pattern generator 2, specifies the coordinate of each photosensor 40 (step S114), and sets the projection image range 172 from the coordinate of each specified photosensor 40. calculate. Thereafter, the control unit 1 performs the determination process of step 112 again. Here, the process of step S114 is the same as the process of step S100. Note that in the image projection position adjustment by the fifth axis adjustment mechanism, only the horizontal direction adjustment of the projection image with respect to the frame 171 is performed.

  The processes in steps S112 to S114 are repeated until the interval between the left end of the projection image and the left side of the frame 171 matches the interval between the right end of the projection image and the right side of the frame 171.

  Through the processing in steps S109 to S114, the center of the projection image matches the center of the frame of the screen 5. FIG. 21 shows a projected image range 182 whose center coincides with the center of the frame of the screen 5. In FIG. 21, a frame 181 corresponds to the display screen frame of the screen 5.

  If it is determined in step S112 that the interval between the left end of the projection image and the left side of the frame of the screen 5 matches the interval between the right end of the projection image and the right side of the frame of the screen 5, the control unit 1 The coordinates P4, Q4, R4, and S4 of the pixels at the four corners of the projected image range 182 shown in FIG. Then, the control unit 1 determines whether or not the coordinates of the four corners of the range (frame) of the display screen of the screen 5 obtained based on the coordinates of each optical sensor 40 match the coordinates P4, Q4, R4, and S4, respectively. (Step S115).

  When it is determined in step S115 that the coordinates of the four corners of the display screen frame of the screen 5 do not match the coordinates P4, Q4, R4, and S4 of the four corner pixels of the projected image range 182, the control unit 1 The sixth axis adjustment mechanism of the six-axis drive unit 3 is controlled to adjust the image projection position (step S116). And the control part 1 produces | generates a 2nd pattern in the pattern generator 2, specifies the coordinate of each optical sensor 40 (step S117), and sets the projection image range 182 from the coordinate of each specified optical sensor 40. calculate. Thereafter, the control unit 1 performs the determination process of step 115 again. Here, the process of step S117 is the same as the process of step S100. In the image projection position adjustment by the sixth axis adjustment mechanism, only the enlargement or reduction of the projection image is performed.

  The processing in steps S115 to S117 is repeated until the coordinates of the four corners of the display screen of the screen 5 coincide with the coordinates P4, Q4, R4, and S4 of the four corner pixels of the projected image range 182 respectively. FIG. 22 shows a state where the coordinates of the four corners of the display screen of the screen 5 coincide with the coordinates of the four corner pixels of the projection image range. In FIG. 22, a frame 191 corresponds to the frame of the display screen of the screen 5. The coordinates of the four corners of the frame 191 correspond to the coordinates of each optical sensor 40. The coordinates of the four corners of the frame 191 coincide with the coordinates of the pixels at the four corners of the projection image range 192.

  In the second image projection position adjustment process described above, the second pattern may be a pattern in which all the pixels on the image forming surface are sequentially turned on in a predetermined order.

  According to the rear projector of the present embodiment described above, the 6-axis adjustment can be automatically performed so that the range of the projected image and the range of the screen display screen coincide with each other, so that compared with a case where manual adjustment work is performed. Adjustment time can be shortened.

  In addition, the optical sensor unit is configured to detect light from the display screen through a window having a size (specified pixel size) defined by the size of the display screen and the maximum resolution of the projector. It is possible to calculate the position of the optical sensor unit at a precision equal to or less than the prescribed pixel size. Therefore, the adjustment accuracy of the image projection position can be improved as compared with the case where manual adjustment work is performed.

  Note that if the size of the window is too small compared to the prescribed pixel size, it is difficult to calculate the coordinates of the position of the photosensor based on the ratio of the amount of light from the four pixels as shown in FIG. In this case, since the number of pixels that can detect light through the window is one, the position of the optical sensor unit is indicated by the coordinates of the pixels, so that the adjustment accuracy of the image projection position decreases. On the other hand, even when the size of the window is too large compared to the prescribed pixel size, it is difficult to calculate the coordinates of the position of the photosensor based on the ratio of the amount of light from the four pixels as shown in FIG. In this case, the amount of light from each pixel becomes substantially equal, so the position of the photosensor cannot be calculated accurately. For this reason, in order to achieve high-accuracy adjustment of the image projection position, the size of the window is determined based on the coordinates of the position of the photosensor based on the ratio of the amount of light from the four pixels as shown in FIG. It is necessary to make it a size that can be calculated, more preferably a specified pixel size.

  Further, according to the rear projector of the present embodiment, the optical sensor units 4a to 4d need only fix the second and third plate members to the corners of the screen as shown in FIG. There is little burden.

  Furthermore, according to the method of calculating the position of the light sensor from the ratio of the light amounts of the four pixels, the position of the light sensor can be accurately calculated even when the focus of the projector is not optimally adjusted.

  Next, a multi-screen rear projector to which the rear projector of the present invention is applied will be described.

  FIG. 23 is a schematic diagram illustrating an example of a multi-screen rear projector. This multi-screen rear projector is configured by connecting first to fourth rear projectors. In FIG. 23, screens 21 to 24 are screens of the first to fourth rear projectors, respectively.

  At the four corners of each of the screens 21 to 24, optical sensor units having the configurations shown in FIGS. 8 and 9 are attached. For example, when the optical sensor unit is attached to the upper right corner of the screen 21, the first plate member of the first to third plate members constituting the light shielding plate 41 is in close contact with the display surface of the screen 21. Each surface of the second and third plate members is fixed so as to be in close contact with the adjacent side portions of the corners of the screen 21. The third plate member is fixed while being sandwiched between the sides of the screens 21 and 22.

  Also in the multi-screen rear projector shown in FIG. 23, automatic adjustment of the image projection position by six axes is performed in each rear projector using the optical sensor unit having the configuration shown in FIGS. By this automatic adjustment, the installation work of the multi-screen rear projector can be easily performed.

  Further, since the optical sensor 40 is accommodated in a shielding space formed by the cover 42 and the light shielding plate 41, light from other screens does not enter the optical sensor 40.

  The rear projector of the present embodiment described above is an example of the present invention, and the configuration and operation thereof can be changed as appropriate without departing from the spirit of the invention.

  For example, in the operation of the rear projector of the present embodiment described above, adjustment is performed while calculating the control amount for each axis, but the present invention is not limited to this. The positions (coordinates) of the photosensors at the four corners are calculated in step S100 of FIG. 11, and the display screen range obtained from the positions of the photosensors and the range of the projected image are required to match with each axis. The control amount may be calculated and adjustment by each axis may be performed. As a result, the time required for adjustment can be further shortened.

  The adjustable axes are not limited to six axes. Any number of adjustment axes may be used as long as the image projection position can be adjusted.

  Further, the number of the optical sensor units is not limited to four. If the projected image can be accurately calculated, five or more photosensor units may be attached.

It is a block diagram which shows the structure of the rear projector which is one Embodiment of this invention. It is a mimetic diagram showing an example of position adjustment by the 1st axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 1st axis adjustment mechanism. It is a mimetic diagram showing an example of position adjustment by the 2nd axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 2nd axis adjustment mechanism. It is a mimetic diagram showing an example of position adjustment by the 3rd axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 3rd axis adjustment mechanism. It is a mimetic diagram showing an example of position adjustment by the 4th axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 4th axis adjustment mechanism. It is a mimetic diagram showing an example of position adjustment by the 5th axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 5th axis adjustment mechanism. It is a mimetic diagram showing an example of position adjustment by the 6th axis adjustment mechanism. It is a mimetic diagram showing other examples of position adjustment by the 6th axis adjustment mechanism. It is a disassembled perspective view which shows an example of the optical sensor part used for the rear projector shown in FIG. It is a schematic diagram which shows one example of arrangement | positioning of the window of the optical sensor shown in FIG. It is a flowchart which shows one procedure of the 1st image projection position adjustment process performed with the rear projector shown in FIG. It is a flowchart which shows one procedure of the 2nd image projection position adjustment process performed with the rear projector shown in FIG. It is a schematic diagram which shows the lighting operation of the pixel in the corner | angular area | region of a projection image. It is a schematic diagram which shows the positional relationship of a projection image and a window. It is a schematic diagram at the time of seeing the positional relationship shown in FIG. 13 from the display screen side of the screen. It is a figure which shows the light quantity detected with an optical sensor through the window at the time of lighting four pixels in order in the state shown in FIG. It is a schematic diagram which shows the coordinate of four optical sensors on a virtual image display area. It is a schematic diagram which shows the positional relationship of the range of a projection image, and the frame of the display screen of a screen. It is a schematic diagram which shows the positional relationship of the range of the projection image which the upper and lower ends became parallel, and the frame of the display screen of a screen. It is a schematic diagram which shows the positional relationship of the range of the projection image in which the right and left ends became parallel, and the frame of the display screen of a screen. It is a schematic diagram which shows the range of the projection image in which the upper end became parallel to the upper side of the frame of the display screen of a screen. It is a schematic diagram which shows the range of the projection image in which the center corresponded with the center of the frame of the display screen of a screen. It is a schematic diagram which shows the state which the coordinate of the four corners of the display screen of a screen corresponded with the coordinate of the pixel of the four corners of the range of a projection image, respectively. It is a schematic diagram which shows an example of the multi-screen rear projector which is other embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Control part 2 Pattern generator 3 6-axis drive part 4a-4d Optical sensor part 5 Screen 6 Projector

Claims (7)

A projector that projects an image composed of a plurality of pixels onto a screen;
Four photosensors provided at the four corners on the display screen on the side opposite to the projector of the screen;
An axis drive unit comprising a plurality of axes intersecting with each other, and rotating and moving the projector around and in the direction of each axis;
A pattern generator for generating a test pattern for sequentially lighting pixels in the four corner areas of the image;
A control unit that performs a display operation by the projector and controls the driving unit to adjust an image projection position of the projector with respect to the screen;
Each of the four photosensor units includes a window having a size defined by a size of the display screen and a resolution indicating a density of pixels that can be displayed on the display screen by the projector, and the display through the window. Detect light from the screen,
The control unit causes the projector to project an image based on the test pattern generated by the pattern generator, the lighting timing of each pixel in the four corner regions of the projected image, and the four lighting timings of each pixel. The positions of the four photosensor units on the projection image are acquired based on the output values of the two photosensor units, and the range of the display screen obtained based on the positions matches the range of the projection image. A rear projector for controlling the driving unit. The pattern generator generates another test pattern for lighting all the plurality of pixels simultaneously,
The control unit causes the projector to project an image based on another test pattern generated by the pattern generator before deciding the positions of the four photosensor units, and includes the projection image in the region of the projection image. The rear projector according to claim 1, wherein the driving unit is controlled such that four optical sensor units are positioned.   Each of the four optical sensor units includes a light shielding plate on which the window is formed, and the shortest length from the edge of the window to the edge of the light shielding plate is the size of the display screen and the projector displays the display. The rear projector according to claim 1, wherein the rear projector has a length equal to or greater than a pixel size defined by a maximum resolution value indicating a density of pixels that can be displayed on a screen.   The rear projector according to claim 1, wherein the window has a quadrangular shape.   5. The rear projector according to claim 3, wherein each of the four optical sensor units includes two plate members that are orthogonal to the light shielding plate and are joined to two adjacent sides of the light shielding plate. An image projection position adjustment method for a projector that projects an image composed of a plurality of pixels onto a screen,
In the four corner areas of the image, generate a test pattern for sequentially lighting the pixels in the area,
Projecting an image based on the test pattern by the projector,
In the four photosensor units provided at the four corners on the display screen opposite to the projector on the screen, the size of the display screen and the density of pixels that the projector can display on the display screen are shown. Detecting light from the display screen through a window of a size defined by the resolution,
The projection images of the four photosensor units based on the lighting timing of each pixel in the four corner regions of the projection image based on the test pattern and the output values of the four photosensor units at the lighting timing of the pixels. An image obtained by acquiring a position on the screen and rotating or moving the projector around or in a predetermined axis so that a range of the display screen and a range of the projection image obtained based on the position coincide with each other Projection position adjustment method.   Before the test pattern is generated, another test pattern for lighting all the plurality of pixels at the same time is generated, an image based on the other test pattern is projected by the projector, and the four optical sensors are projected on the projected image. The image projection position adjustment method according to claim 6, wherein the projector is rotated or moved so that the unit is positioned.

Images