JP2009077167A - Video adjustment system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video adjustment system by which relative positioning of video images projected from a plurality of projectors is allowed using a test video image output from a single video output terminal. <P>SOLUTION: A video generator has: generation means for generating a single test video image including a plurality of patterns Pa, Pb for adjustment associated with each projector, respectively; and a video output terminal which projects the patterns Pa, Pb for adjustment from each projector by outputting a video signal of the test video image to each projector. Each of the patterns Pa, Pb for adjustment is composed of a graphic constituting the cross shape by a vertical side and a horizontal side. Here, attributes different from each other are given to each of the patterns Pa, Pb for adjustment by setting the pattern Pa for adjustment corresponding to a first projector so that its horizontal side is longer on the left side rather than on the right side of its vertical side, and setting the pattern Pb for adjustment corresponding to a second projector so that its horizontal side is longer on the right side rather than on the left side of the vertical side. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an image adjustment system that performs relative alignment of images from each projector in order to project an image on a single screen using a plurality of projectors.

  Conventionally, a technique for projecting an image on a single screen using a plurality of projectors is known. If this technology is used, for example, one image is divided into a plurality of images and projected from each projector so that the periphery of the images from each projector overlap each other, so that one image before division is displayed on the screen. One video can be displayed (see, for example, Patent Document 1).

  As described above, when a plurality of projectors are used to project an image on a single screen, it is necessary to match the relative positions of the images from the projectors in order to present the correct image to the observer without distortion. For example, as described above, when a divided image is projected from each projector and one image before the division is displayed on the screen, the relative position of the image from each projector is adjusted so that the joint and distortion can be reduced. One video that is not present can be displayed.

Therefore, in general, a video generation device that forms a video adjustment system together with a plurality of projectors is used to perform relative positioning of video from each projector. The video generation apparatus generates a test video for projecting an adjustment pattern for alignment from each projector. Thus, if a video generation device is connected to each projector, and individual adjustment patterns corresponding to individual projectors are simultaneously projected onto the screen from each projector, the relative positions of the projected adjustment patterns are aligned. Thus, relative alignment of images projected from a plurality of projectors can be performed.
JP 2006-516333 A

  By the way, in the above-described video adjustment system, since the adjustment patterns are simultaneously projected from the projectors, the same number of video generation apparatuses as the test video are required as the projectors, and it is troublesome to arrange the video generation apparatuses and secure the installation location. It takes. It is possible to use a video generation device having a plurality of video output terminals and output individual test videos from each video output terminal to combine the video generation devices into one unit. A highly portable video generation device such as a notebook personal computer is used, and there are few such video generation devices having a plurality of video output terminals.

  The present invention has been made in view of the above circumstances, and performs relative alignment of images projected from a plurality of projectors using a test image output from a single image output terminal. An object of the present invention is to provide an image adjustment system capable of

  The invention of claim 1 includes a plurality of projectors that project images onto one screen, and a video generation device that generates a test video for projecting an adjustment pattern from each projector. Image adjustment that adjusts the relative position of the adjustment patterns corresponding to the projector that is the projection source, and adjusts the relative position of the images from each projector, while projecting the adjustment patterns from the projector at the same time. In the system, the video generation device generates a single test video including a plurality of types of adjustment patterns respectively associated with the projectors, and outputs a video signal of the test video to each projector And a video output terminal for projecting an adjustment pattern from each projector, The Murrell each adjustment pattern, as distinguished from the adjustment pattern each other corresponding to the projection source of the projector is possible on the screen, each different attributes and wherein the granted.

  According to this configuration, since the generation unit generates a single test video including a plurality of types of adjustment patterns respectively associated with each projector, the test video output from a single video output terminal is used. Thus, the adjustment pattern can be projected simultaneously from a plurality of projectors. In addition, since each adjustment pattern included in the test video has different attributes so that adjustment patterns corresponding to the projection source projectors can be distinguished on the screen, a plurality of adjustment patterns are provided. With the adjustment pattern projected from the projector at the same time, it is possible to identify which adjustment pattern corresponds to which projector, and match the relative positions of the adjustment patterns corresponding to the projection source projector. As a result, the relative position of the images from the projectors can be adjusted.

  According to a second aspect of the present invention, in the first aspect of the invention, the plurality of projectors are arranged such that projection areas for projecting the respective images overlap each other on the screen, and The image is divided into images and projected from each projector, and one image before division is displayed on the screen.

  According to this configuration, in a so-called multi-projection system in which one video is divided into a plurality of videos and projected from each projector, and one video before division is displayed on the screen, a single video output terminal is used. Using the output test video, it is possible to perform relative alignment of the video projected from a plurality of projectors.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, between the projector and the screen, of the projection light of the test image projected from each projector, the projection source projector A shielding filter that shields projection light of an adjustment pattern other than the corresponding adjustment pattern is provided.

  According to this configuration, since the projection light of the adjustment pattern unnecessary for the relative alignment of the images from the projectors is shielded, only the adjustment pattern necessary for the alignment is displayed on the screen. Thus, there is an advantage that the alignment operation is simplified as compared with the case where both the adjustment pattern unnecessary for the alignment and the necessary adjustment pattern are displayed.

  According to a fourth aspect of the present invention, in the invention according to any one of the first to third aspects, the projector is capable of projecting light of a plurality of colors, and the generator is configured to adjust each of the projectors associated with each projector. It is characterized in that the working patterns have different colors.

  According to this configuration, since the adjustment pattern has a different color for each corresponding projector, the adjustment patterns corresponding to the projection source projector can be easily distinguished from each other. The relative alignment work of each becomes easy.

  According to a fifth aspect of the present invention, in the fourth aspect of the invention, the projector corresponds to a video input terminal that receives a video signal from the video output terminal through a separate signal line for each color of the video, respectively. Color selection means for selecting a combination of signal lines by color so that only the video signal of the color of the adjustment pattern is input.

  According to this configuration, since only the adjustment pattern necessary for the relative alignment of the images from the projectors is displayed on the screen, the adjustment pattern unnecessary for the alignment and the necessary adjustment pattern are displayed. As compared with the case where both are displayed, there is an advantage that the positioning operation is simplified.

  According to a sixth aspect of the present invention, in the fourth aspect of the present invention, the adjustment corresponding to the projection source projector among the projection lights of the test video projected from the projectors between the projector and the screen. A color filter that blocks light of an adjustment pattern color other than the adjustment pattern is provided.

  According to this configuration, since only the adjustment pattern necessary for the relative alignment of the images from the projectors is displayed on the screen, the adjustment pattern unnecessary for the alignment and the necessary adjustment pattern are displayed. As compared with the case where both are displayed, there is an advantage that the positioning operation is simplified.

  According to a seventh aspect of the invention, in the invention of the fourth aspect, the projector adjusts the hue of the projection light so that the projector does not project the light of the color of the adjustment pattern other than the adjustment pattern corresponding to the projector. It has the means.

  According to this configuration, since only the adjustment pattern necessary for the relative alignment of the images from the projectors is displayed on the screen, the adjustment pattern unnecessary for the alignment and the necessary adjustment pattern are displayed. As compared with the case where both are displayed, there is an advantage that the positioning operation is simplified.

  According to an eighth aspect of the present invention, in the invention according to any one of the first to third aspects, the generation unit is configured to draw each adjustment pattern associated with each projector with a different drawing pattern. It is characterized by that.

  According to this configuration, since the adjustment pattern is drawn with a different drawing pattern for each corresponding projector, it is easy to distinguish between the adjustment patterns corresponding to the projection source projector. The relative positioning of the image from the projector is facilitated.

  According to the present invention, a video generation device generates a single test video including a plurality of types of adjustment patterns respectively associated with each projector, and outputs a video signal of the test video to each projector And an image output terminal for projecting an adjustment pattern from each projector, and each adjustment pattern included in the test image can be distinguished from the adjustment pattern corresponding to the projection source projector on the screen. Since different attributes are assigned to each other, relative alignment of images projected from a plurality of projectors can be performed using a test image output from a single image output terminal. There is an advantage.

(Embodiment 1)
In the present embodiment, as shown in FIG. 2A, by projecting images from a plurality of projectors 2a and 2b on one screen 1 at the same time, there is one joint and no distortion on the screen 1. An image adjustment system that performs relative alignment of images from the projectors 2a and 2b will be described by taking a so-called multi-projection system that displays images as an example. Here, the screen 1 is a curved screen (dome-shaped screen) that is larger than the image viewer H and has a concave curved surface in which the image projection surface forms a part of a substantially spherical surface. Since this type of multi-projection system can display a large image over a wide field of view, it can give multiple viewers the immersive feeling of being in virtual space at the same time. It is used for various purposes such as amusement that the viewer enjoys by projecting images and fire evacuation drills.

  In the example shown in FIG. 2, two projectors 2a and 2b that project an image onto the screen 1 are provided. Each of the projectors 2a and 2b is shown in FIG. In this way, it is arranged to project an image on each of the projection areas Xa and Xb arranged in the left-right direction. Here, the projection areas Xa and Xb of the projectors 2a and 2b are substantially rectangular when viewed from the front, and are set so as to at least partially overlap the adjacent projection areas Xa and Xb. , 2b are connected to each other so that one image can be displayed on the screen 1. In short, in this embodiment, one video is divided into a plurality of (here, two) videos (hereinafter referred to as divided images) and projected from the projectors 2a and 2b, respectively. One video can be displayed.

  By the way, if the relative positions of the divided video projected by one projector 2a and the divided video projected by the other projector 2b are shifted, the video is displayed in the overlapping portion of the projection areas Xa and Xb of the projectors 2a and 2b. In order to connect the divided images projected from the plurality of projectors 2a and 2b and display one image without a seam or distortion on the screen 1, a plurality of distortions are generated. It is necessary to perform relative alignment of images projected from the projectors 2a and 2b.

  Therefore, the image adjustment system of the present embodiment is connected to a plurality of projectors 2a and 2b as shown in FIG. 2A in order to perform relative alignment of the images from the projectors 2a and 2b. One video generation device 3 is provided.

  The image generation device 3 generates test images for projecting the adjustment patterns Pa and Pb (see FIG. 1) from the projectors 2a and 2b, respectively. Thus, in the image adjustment system, the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b are relative to each other in a state where the adjustment patterns Pa and Pb are simultaneously projected from the plurality of projectors 2a and 2b. By aligning the correct positions, the relative positions of the images from the projectors 2a and 2b are adjusted. In the present embodiment, the video display position is adjusted by adjusting the video correction parameter for determining the video display position in the projection areas A and Ab for each of the projectors 2a and 2b.

  Here, the video generation device 3 includes a generation unit (not shown) that generates a single test video including a plurality of types of adjustment patterns Pa and Pb respectively associated with the projectors 2a and 2b, and a generation unit. And a single video output terminal T for projecting the adjustment patterns Pa and Pb from the projectors 2a and 2b by outputting the video signals of the test video generated in step S2 to the projectors 2a and 2b. In the present embodiment, a portable notebook computer having high portability is used as the video generation device 3.

  Hereinafter, an operation of the video generation device 3 when the generation unit generates a test video will be described.

  The video generation device 3 is set and inputted with adjustment parameters including position information of the projectors 2a and 2b, projection angle of view, the shape of the screen 1, the viewpoint position of the observer H, and the like. In addition, among the projection areas Xa and Xb, the evaluation areas Ya and Yb necessary for evaluating the relative positional relationship of the images are specified and calculated for each projector 2a and 2b. That is, in the projectors 2a and 2b, the entire area of the projection areas Xa and Xb is not used for evaluating the relative positional relationship between the images. For example, the adjacent projection areas Xa and Xb of the projection areas Xa and Xb The vicinity of the seam is used for evaluation of the relative positional relationship of the video as the respective evaluation areas Ya and Yb. In the present embodiment, for each projector 2a and 2b, the projection areas Xa and Xb are divided into the same number as the number of the projectors 2a and 2b in the direction in which the plurality of projection areas Xa and Xb are arranged, and are adjacent among the divided areas. Areas that overlap the projection areas Xa and Xb are calculated as evaluation areas Ya and Yb.

  In short, as shown in FIG. 2B, when both projection areas Xa and Xb overlap at the center of the projection surface of the screen 1 in the left-right direction, the image is displayed on the left projection area Xa when the projection surface of the screen 1 is viewed from the front. In the projector (hereinafter referred to as the first projector) 2a that projects the right edge of the projection area Xa overlaps the other projection area Xb, the right half of the projection area Xa is evaluated as shown in FIG. On the other hand, in the projector (hereinafter referred to as the second projector) 2b that is calculated as the area Ya and projects an image on the right projection area Xb, the left end of the projection area Xb overlaps the other projection area Xa. As shown in (a), the left half of the projection area Xb is calculated as the evaluation area Yb.

  Further, the generation unit of the video generation device 3 generates the adjustment patterns Pa and Pb associated with the projectors 2a and 2b in the evaluation areas Ya and Yb, respectively, based on the adjustment parameters. Each of the adjustment patterns Pa and Pb generated at this time is made up of an image in which a unique attribute is given to each projector 2a and 2b in order to make it possible to distinguish between the corresponding projectors 2a and 2b. Specifically, the adjustment patterns Pa and Pb generated in the evaluation areas Ya and Yb are respectively parallel to the sides of the projection areas Xa and Xb of the projectors 2a and 2b as shown in FIG. It consists of figures that form a cross with the vertical and horizontal sides. Here, the adjustment pattern Pa corresponding to the first projector 2a is set to have a longer horizontal side on the left side than the right side of the vertical side, while the adjustment pattern Pb corresponding to the second projector 2b is set to the vertical side. The horizontal side is set longer from the left side to the right side.

  The video generation device 3 superimposes the two videos generated with the adjustment patterns Pa and Pb in the respective evaluation areas Ya and Yb as described above to form a single test video as shown in FIG. Generate. The test video generated in this way is output as a video signal from the video output terminal T of the video generation device 3 to the projectors 2a and 2b, whereby the adjustment pattern Pa is applied to the screen 1 from each of the projectors 2a and 2b. , Pb are projected. Here, since different adjustment attributes are given to the adjustment patterns Pa and Pb included in the test video by the generation unit, the adjustment patterns Pa and P corresponding to the projection projectors 2a and 2b on the screen 1 are provided. Pb can be distinguished from each other.

  Accordingly, when a plurality of types of adjustment patterns Pa and Pb respectively associated with the projectors 2a and 2b are simultaneously projected onto a single screen 1 from a plurality (two in this case) of projectors 2a and 2b, FIG. As shown in FIG. 1 (a), adjustment patterns Pa and Pb are respectively projected on the projection areas Xa and Xb of the projectors 2a and 2b on the screen 1, and a total of four adjustment patterns Pa and Pb are displayed on the entire screen 1. Is done. At this time, in the portion where the plurality of projection areas Xa and Xb overlap on the screen 1 (the central portion in the left-right direction of the screen 1), the respective projections of the adjustment patterns Pa and Pb projected from the projectors 2a and 2b. Adjustment patterns Pa and Pb corresponding to the original projectors 2a and 2b are displayed. Here, with respect to the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b that are the projection sources, the video correction parameters of the projectors 2a and 2b are adjusted so that the positions of the intersections of the vertical and horizontal sides are matched. As a result, relative positioning of the images from the projectors 2a and 2b is performed. That is, the video correction parameters of the projectors 2a and 2b are adjusted so that the vertical sides and the horizontal sides of the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b are aligned in a straight line. Is done.

  Here, in the present embodiment, for each projector 2a, 2b, the video correction parameter for determining the position of the corresponding adjustment pattern Pa, Pb in the test video can be adjusted in the video generation device 3, and the video correction parameter By adjusting the positions of the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b on the screen 1 according to the change, the adjustment patterns Pa and Pb are aligned with each other. The image correction parameters adjusted in this way are reflected on the projectors 2a and 2b, respectively, and are reflected on the display positions of the images actually projected from the projectors 2a and 2b.

  In short, in the example shown in FIG. 1A, when the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b are compared, the adjustment pattern Pb projected from the second projector 2b is the first pattern. Since the position is shifted to the lower left with respect to the adjustment pattern Pa projected from the projector 2a, for example, as shown in FIG. 1B, adjustment corresponding to the second projector 2b is performed by adjusting the video correction parameter. By shifting the adjustment pattern Pb to the upper right relative to the other adjustment pattern Pa, the positions of the intersections of the two adjustment patterns Pa and Pb can be matched. In this case, by reflecting the video correction parameters to the projectors 2a and 2b, the display position of the video from the second projector 2b is relatively upper right relative to the display position of the video from the first projector 2a. And the relative positioning of the images from the projectors 2a and 2b is performed.

  Note that the relative positional relationship between the adjustment patterns Pa and Pb in the test image may be fixed, and the adjustment patterns Pa and Pb may be integrally shifted in the vertical and horizontal directions according to the video correction parameter. In this configuration, by adjusting the image correction parameter and adjusting the display positions of the adjustment patterns Pa and Pb in the projection areas Xa and Xb for each of the projectors 2a and 2b, the intersection points of the two adjustment patterns Pa and Pb are adjusted. So that the images from the projectors 2a and 2b are aligned relative to each other.

  Further, here, the image correction parameters are manually adjusted so that the positions of the adjustment patterns Pa and Pb are aligned while a person visually confirms the positions of the adjustment patterns Pa and Pb projected on the screen 1. However, for example, the adjustment patterns Pa and Pb projected on the screen 1 are imaged by a camera, and the positions of the adjustment patterns Pa and Pb are aligned while checking the positions of the imaged adjustment patterns Pa and Pb. In addition, an automatic adjustment device that automatically adjusts the video correction parameter may be included in the components of the video adjustment system.

  As described above, by aligning the positions of the plurality of types of adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b that are the projection sources, the images from the projectors 2a and 2b are relatively aligned, As a result, when the divided images projected from the plurality of projectors 2a and 2b are connected, one image without a joint or distortion can be displayed on the screen 1.

  By the way, the adjustment patterns Pa and Pb shown in FIGS. 1 and 3 are merely examples, and the adjustment patterns Pa and Pb are the positional information and projection angle of view of each projector 2a and 2b, the shape of the screen 1, and the observer. It is appropriately generated according to the adjustment parameter including information such as the H viewpoint position.

  For example, in a stereoscopic video display system in which two videos with parallax are projected from the projectors 2a and 2b onto the screen 1 and the viewer H sees the stereoscopic video, the multi-projection system described in the above embodiment is generally used. Compared with the projection area Xa of the 1st projector 2a, the overlap area of the projection area Xb of the 2nd projector 2b becomes large. In this case, the adjustment patterns Pa and Pb in FIG. 4A in which the distance between the adjustment patterns Pa and Pb is smaller than the adjustment patterns Pa and Pb in FIG. In the adjustment patterns Pa and Pb shown in FIG. 4A, the adjustment pattern Pa corresponding to the first projector 2a is set so that the horizontal side is longer on the right side than the left side of the vertical side, while the second projector The adjustment pattern Pb corresponding to 2b is set to have a longer horizontal side on the left side than the right side of the vertical side. Even in this case, as shown in FIG. 4B, the positions of the intersections of the vertical and horizontal sides of the two adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b that are the projection sources are matched to each other. The relative positioning of the images from the projectors 2a and 2b is performed.

(Embodiment 2)
The image adjustment system according to the first embodiment is configured such that adjustment patterns Pa and Pb other than the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b that are the projection sources are not displayed on the screen 1. Different from the system.

  That is, in the video adjustment system of the first embodiment, for example, when the overlapping area between the projection areas Xa and Xb is large as illustrated in FIG. 4, the adjustment patterns Pa and Pb projected from the projectors 2a and 2b are used. Of these, not only the adjustment patterns Pa and Pb necessary for the relative alignment of the images from the projectors 2a and 2b (that is, corresponding to the projection projectors 2a and 2b), but also other adjustment patterns Pa , Pb are also displayed in the overlapping portions of the projection areas Xa, Xb, making it difficult to distinguish between the adjustment patterns Pa, Pb necessary for the alignment and the unnecessary adjustment patterns Pa, Pb. Sometimes.

  Therefore, in the present embodiment, among the adjustment patterns Pa and Pb projected from the projectors 2a and 2b, the adjustment patterns Pa and Pb other than the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b that are the projection sources are Prevent it from being displayed on screen 1. In short, a shielding filter that shields the projection light of the adjustment patterns Pa and Pb other than the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b is attached to the projectors 2a and 2b. Only the adjustment patterns Pa and Pb are projected onto the screen 1. Specifically, as shown in FIG. 5A, in the first projector 2a, the left half of the projection area Xa is covered with the shielding filter 4, and in the second projector 2b, the right half of the projection area Xb is shielded. Covered with a filter 4.

  As a result, only the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b are projected from the projectors 2a and 2b as shown in FIG. 5A. Therefore, the adjustment patterns as shown in FIG. Pa and Pb can be easily aligned. As described above, when the adjustment patterns Pa and Pb unnecessary for image alignment are not displayed among the adjustment patterns Pa and Pb, the screen is compared with the case where all the adjustment patterns Pa and Pb are displayed. Since the display on 1 is simplified and there is no confusing display, the display position of the video can be easily adjusted.

  Other configurations and functions are the same as those of the first embodiment.

(Embodiment 3)
The video adjustment system of the present embodiment is different from the video adjustment system of the first embodiment in that a technique for easily distinguishing the adjustment patterns Pa and Pb on the screen 1 is employed.

  That is, in the video adjustment system of the first embodiment, although the projection projectors 2a and 2b can be identified for each of the adjustment patterns Pa and Pb due to the difference in shape of the adjustment patterns Pa and Pb, the adjustment patterns Pa, If a plurality of adjustment patterns Pa and Pb are displayed in an overlapping manner when performing alignment between Pb, it is difficult to distinguish between the adjustment patterns Pa and Pb, and the projection sources of the adjustment patterns Pa and Pb are difficult to distinguish. It may be difficult to identify the projectors 2a and 2b. In this case, in order to align the positions of the adjustment patterns Pa and Pb, it is difficult to understand which adjustment patterns Pa and Pb corresponding to which projectors 2a and 2b should be shifted, and it is difficult to adjust the display position of the image. Become.

  Therefore, in the present embodiment, as shown in FIG. 6A, the adjustment patterns Pa and Pb are represented by different line types for the corresponding projectors 2a and 2b, respectively, thereby distinguishing the adjustment patterns Pa and Pb from each other. It is easy to stick. In the example shown in FIG. 6A, different drawing patterns (shaded, shaded, etc.) are applied to the adjustment patterns Pa and Pb, and the adjustment pattern Pa corresponding to the first projector 2a is the upper right. The adjustment pattern Pb corresponding to the second projector 2b is drawn with a diagonal line hung from the upper left to the lower right. In this example, even if the adjustment patterns Pa and Pb are simultaneously projected from the plurality of projectors 2a and 2b, the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b have different line types. The projectors 2a and 2b that are projection sources of the adjustment patterns Pa and Pb can be easily identified, and the display position of the video can be easily adjusted.

  Here, among the adjustment patterns Pa and Pb projected from the projectors 2a and 2b, the adjustment patterns Pa and Pb other than the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b are displayed on the screen 1. May not be displayed.

  In short, for each projector 2a, 2b, a filter for each pattern (not shown) that blocks projection light of a drawing pattern applied to the adjustment patterns Pa, Pb other than the corresponding adjustment patterns Pa, Pb. And the projectors 2a and 2b project only the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b onto the screen 1, respectively. The pattern-specific filter is obtained by applying the same drawing pattern as the shielding target adjustment patterns Pa and Pb to the shielding pattern having the light shielding property. The shielding pattern drawing pattern is used as the adjustment pattern Pa and Pb drawing pattern. By overlapping, the projection light of the adjustment patterns Pa and Pb is shielded. For example, if a pattern-specific filter in which a vertical stripe shielding pattern is formed is used, an adjustment pattern having the same drawing pattern (vertical stripe) can be shielded. As a result, the display on the screen 1 is simplified and there is no confusing display as compared with the case where all the adjustment patterns Pa and Pb are displayed, so that the adjustment patterns Pa and Pb can be easily aligned. Can do. When the projection light is shielded by the pattern-specific filter, the light is projected linearly on the screen 1 like a laser projector instead of the projectors 2a and 2b that collect the light on the lens and form an image on the screen 1. It is desirable to use projectors 2a and 2b capable of illuminating.

  By the way, as another example of the present embodiment, different colors (for example, two colors of red and blue) are selected from the light colors that can be projected by the projectors 2a and 2b, and each selected color is used for each adjustment. By representing the patterns Pa and Pb, respectively, the adjustment patterns Pa and Pb may be easily distinguished from each other. Also in this example, since the display colors are different between the adjustment patterns Pa and Pb, the projectors 2a and 2b that are projection sources of the adjustment patterns Pa and Pb can be easily identified, and the display position of the video can be easily adjusted. Become.

  Furthermore, when different colors are applied to the respective adjustment patterns Pa and Pb in this way, the adjustment patterns Pa and Pb other than the adjustment patterns Pa and Pb corresponding to the projection projectors 2a and 2b can be obtained with a simple configuration. It can be prevented from being displayed on the screen 1.

  That is, a color filter (not shown) that blocks light of colors other than the colors of the corresponding adjustment patterns Pa and Pb is attached to each projector 2a and 2b. Only the corresponding adjustment patterns Pa and Pb may be projected onto the screen 1. Each projector 2a, 2b has a video input terminal (not shown) for receiving the video signal from the video output terminal T of the video generation device 3 by an individual color-specific signal line (not shown) for each color of the video. Color selection means (for example, a switch for turning on / off each color-specific signal line) to select a combination of the color-specific signal lines so that only the video signals of the adjustment patterns Pa and Pb corresponding to each of them are input. It is good also as a structure which has. Furthermore, when each projector 2a, 2b has a color adjustment function that adjusts the hue of the projection light, the projector 2a, 2b adjusts the hue of the projection light by using this function. Light of colors other than the adjustment patterns Pa and Pb may not be projected. Thereby, only the adjustment patterns Pa and Pb corresponding to the projectors 2a and 2b are projected from the projectors 2a and 2b, respectively, and the alignment of the adjustment patterns Pa and Pb can be easily performed.

  In each of the adjustment patterns Pa and Pb, the intersection of the vertical side and the horizontal side is represented by a line type (drawing pattern or color) different from that of the other part, so that the adjustment patterns Pa and Pb can be aligned. The part may be displayed particularly clearly. Similarly, the vertical side or the horizontal side may be represented by a line type different from other parts.

  Other configurations and functions are the same as those of the first embodiment.

(Embodiment 4)
The video adjustment system according to the present embodiment is different from the video adjustment system according to the first embodiment in that four projectors 2a to 2d that project images onto the screen 1 are provided as shown in FIG. .

  Each of the projectors 2a to 2d is a projection divided into four sections in total of two rows on the left and right and two on the top and bottom as shown in FIG. 7B when the screen 1 is viewed from the front (projection surface side of the image). It arrange | positions so that an image | video may be projected on area | region Xa-Xd. Here, the projection areas Xa to Xd of the projectors 2a to 2d are each set to be substantially rectangular in front view, and all the projection areas Xa to Xd overlap at the center of the projection surface of the screen 1. By connecting the images from the projectors 2a to 2d, one image can be displayed on the screen 1.

  By the way, since the video adjustment system of the present embodiment is different from the first embodiment in the adjustment parameters, the evaluation areas Ya to Yd calculated for each of the projectors 2a to 2d based on the adjustment parameters are also different from those in the first embodiment. Is different.

  In short, in the projector (hereinafter referred to as the first projector) 2a that projects an image on the upper left projection area Xa when the projection surface of the screen 1 is viewed from the front, the lower right portion of the projection area Xa is the other all projection areas. Since it overlaps with Xb to Xd, the lower right part of the projection area Xa is calculated as the evaluation area Ya. Similarly, in the projector (hereinafter referred to as the second projector) 2b that projects an image on the upper right projection area Xb, the lower left portion of the projection area Xb is calculated as the evaluation area Yb, and the image is projected on the lower left projection area Xc. In the projector (hereinafter referred to as the third projector) 2c, the upper right portion of the projection area Xc is calculated as the evaluation area Yc, and in the projector (hereinafter referred to as the fourth projector) 2d that projects an image on the lower right projection area Xd. The upper left part of the projection area Xd is calculated as the evaluation area Yd.

  The video generation device 3 generates the adjustment patterns Pa to Pd associated with the projectors 2a to 2d in the evaluation areas Ya to Yd calculated as described above, and adjusts to the evaluation areas Ya to Yd, respectively. A single test image is generated by superimposing all the images for which the patterns Pa to Pd are generated. Specifically, as shown in FIG. 8A, the test video is substantially rectangular with each pair of vertical and horizontal sides extending along the sides of the projection areas Xa to Xd of the projectors 2a to 2d. It consists of a grid-like pattern. Furthermore, from the four corners of each of the projection areas Xa to Xd, oblique sides that intersect both the vertical and horizontal sides are extended to the vicinity of the center of each of the projection areas Xa to Xd through the intersections of the vertical and horizontal sides. That is, in each of the evaluation areas Ya to Yd, adjustment patterns Pa to Pd formed by intersecting the vertical side, the horizontal side, and the oblique side are generated.

  Thus, the test video generated by the video generation device 3 is output to a plurality (four in this case) of projectors 2a to 2d, and a plurality of types of adjustment patterns Pa to Pd respectively associated with the projectors 2a to 2d. Are simultaneously projected onto a single screen 1 from a plurality of projectors 2a to 2d, as shown in FIG. 8B, the adjustment pattern Pa is applied to the projection areas Xa to Xd of the projectors 2a to 2d on the screen 1, respectively. To Pd are projected, and a total of 16 adjustment patterns Pa to Pd are displayed on the entire screen 1. At this time, in the portion where the plurality of projection areas Xa to Xd overlap on the screen 1 (the central portion of the screen 1), among the adjustment patterns Pa to Pd projected from the projectors 2a to 2d, the respective projection source projectors 2a. Since the adjustment patterns Pa to Pd corresponding to .about.2d are displayed, as shown in FIG. 8C, the adjustment patterns Pa to Pd corresponding to these projection source projectors 2a to 2d are shown in the vertical and horizontal directions. By adjusting the image correction parameters of the projectors 2a to 2d so that the positions of the intersections of the sides and the oblique sides coincide with each other, the relative alignment of the images from the projectors 2a to 2d is performed. . That is, for all the adjustment patterns Pa to Pd corresponding to the projection projectors 2a to 2d, the vertical sides and the horizontal sides are aligned in a straight line to form a cross, and the hypotenuse passes through the center of the cross. The video correction parameters of the projectors 2a to 2d are adjusted so as to form the shape.

  In short, in the example shown in FIG. 8B, when the adjustment patterns Pa to Pd corresponding to the projection projectors 2a to 2d are compared, the adjustment patterns projected from the third and fourth projectors 2c and 2d are used. The patterns Pc and Pd are displaced downward with respect to the adjustment patterns Pa and Pb projected from the first and second projectors 2a and 2b, and correspond to the second and fourth projectors 2b and 2d. Since the adjustment patterns Pb and Pd to be shifted are shifted to the left with respect to the adjustment patterns Pa and Pc projected from the first and third projectors 2a and 2c, the image correction parameter is adjusted, for example, The adjustment patterns Pc and Pd corresponding to the third and fourth projectors 2c and 2d are shifted upward relative to the other adjustment patterns Pa and Pb. In addition, all the adjustment patterns Pb and Pd corresponding to the second and fourth projectors 2b and 2d are shifted to the right relative to the other adjustment patterns Pa and Pc. The position of the intersection of Pa to Pd can be matched.

  As described above, by aligning the positions of the plurality of types of adjustment patterns Pa to Pd corresponding to the projectors 2a to 2d that are the projection sources, the images from the projectors 2a to 2d are relatively aligned, As a result, when the divided images projected from the plurality of projectors 2a to 2d are connected, one image without a joint or distortion can be displayed on the screen 1.

  By the way, also in the said embodiment, it is set as the structure which does not display on the screen 1 adjustment patterns Pa-Pd other than the adjustment patterns Pa-Pd corresponding to the projectors 2a-2d of projection origin as demonstrated in Embodiment 2. FIG. Can do. That is, for example, a shielding filter that shields the projection light of the adjustment patterns Pa to Pd other than the adjustment patterns Pa to Pd corresponding to the projector 2a to 2d is attached to each projector 2a to 2d. As a result, only the adjustment patterns Pa to Pd corresponding to the projectors 2a to 2d are projected from the projectors 2a to 2d as shown in FIG. 9A, and the adjustment patterns Pa to P as shown in FIG. Position alignment between Pd can be easily performed.

  Moreover, in the said embodiment, as demonstrated in Embodiment 3, the technique for making distinction between adjustment pattern Pa-Pd easy on the screen 1 is also employable. That is, for example, as shown in FIG. 10A, the adjustment patterns Pa to Pd are represented by different line types for the corresponding projectors 2a to 2d, respectively, so that the adjustment patterns Pa to Pd can be easily distinguished from each other. . Furthermore, different colors (for example, four colors of red, blue, green, and yellow) are selected from the light colors that can be projected by the projectors 2a to 2d, and the respective adjustment patterns Pa to Pd are selected with the selected colors. By representing each of them, the adjustment patterns Pa to Pd may be easily distinguished. As a result, the projectors 2a to 2d that are projection sources of the adjustment patterns Pa to Pd can be easily identified, and the display position of the video can be easily adjusted. When different colors are applied to the adjustment patterns Pa to Pd, for example, a color filter that blocks light of colors other than the colors of the corresponding adjustment patterns Pa to Pd for each projector 2a to 2d. It is possible to prevent the adjustment patterns Pa to Pd other than the corresponding adjustment patterns Pa to Pd from being displayed with a simple configuration such as attachment.

  Other configurations and functions are the same as those of the first embodiment.

It is explanatory drawing of position alignment of the image | video using the image | video adjustment system of Embodiment 1 of this invention. (A) is the schematic which shows a system configuration same as the above, (b) is the schematic which shows the projection area | region on a screen same as the above. It is explanatory drawing which shows the production | generation process of the adjustment pattern same as the above. It is explanatory drawing of position alignment of the image | video using the image | video adjustment system same as the above. It is explanatory drawing of position alignment of the image | video using the image | video adjustment system of Embodiment 2 of this invention. It is explanatory drawing of position alignment of the image | video using the image | video adjustment system of Embodiment 3 of this invention. (A) is the schematic which shows the system configuration | structure of Embodiment 4 of this invention, (b) is the schematic which shows the projection area | region on the screen same as the above. It is explanatory drawing of position alignment of the image | video using the image | video adjustment system same as the above. It is explanatory drawing of the position alignment of the image | video using the image | video adjustment system of another structure same as the above. It is explanatory drawing of the position alignment of the image | video using the image | video adjustment system of another structure same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Screen 2a-2d Projector 3 Image | video production | generation apparatus 4 Shielding filter Pa-Pd Adjustment pattern T Image | video output terminal

Claims (8)

  Provided with a plurality of projectors that project images onto one screen and a video generation device that generates test images for projecting adjustment patterns from the projectors. A video adjustment system in which the relative positions of the adjustment patterns corresponding to the projection source projectors are aligned in the projected state, and the relative position of the images from the projectors is adjusted. The apparatus includes: a generating unit that generates a single test video including a plurality of types of adjustment patterns respectively associated with each projector; and an adjustment signal from each projector by outputting a video signal of the test video to each projector. A video output terminal for projecting a pattern, and each adjustment pattern included in the test video. The over emissions, image adjustment system, characterized in that as distinguished adjustment patterns each other corresponding to the projection source of the projector is possible, the different attributes are given on the screen.   The plurality of projectors are arranged such that the projection areas for projecting the respective images overlap each other on the screen, and each screen is divided into a plurality of images and projected from each projector, The video adjustment system according to claim 1, wherein one video before division is displayed on the top.   Shielding between the projector and the screen for shielding the projection light of the adjustment pattern other than the adjustment pattern corresponding to the projection source projector among the projection light of the test image projected from each projector. The video adjustment system according to claim 1, further comprising a filter.   4. The projector according to claim 1, wherein the projector is capable of projecting light of a plurality of colors, and the generation unit sets each adjustment pattern associated with each projector to a different color. The video adjustment system according to any one of the above.   The projector receives only a video input terminal that receives a video signal from the video output terminal through a separate signal line for each color of the video, and a video signal of the color of the adjustment pattern corresponding to the video input terminal. 5. The image adjustment system according to claim 4, further comprising color selection means for selecting a combination of signal lines by color.   Between the projector and the screen, light of the color of the adjustment pattern other than the adjustment pattern corresponding to the projection source projector among the projection light of the test image projected from each projector is blocked. The video adjustment system according to claim 4, further comprising a color filter.   5. The image according to claim 4, wherein the projector has color adjusting means for adjusting the hue of the projection light so as not to project the light of the color of the adjustment pattern other than the adjustment pattern corresponding to the projector. Adjustment system.   4. The video according to claim 1, wherein the generation unit draws each adjustment pattern associated with each projector with a different drawing pattern. 5. Adjustment system.

Images