JP2013076949A - Projector device and its control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique in which, in the case where a menu, error, or the like is displayed on a GUI screen, a projector a user uniquely displays them is specified.SOLUTION: Using a geometrical change parameter, the installation position of a projector device is calculated. The installation positions of projector devices other than this projector device are obtained. Using the respective installation positions, the relative positions of the projector device with respect to the other projector devices are specified, and partial areas corresponding to the relative positions in a projection area are determined as GUI display areas. GUI is combined in an area corresponding to each GUI display area in an original image. Using a geometrical change parameter for the composite image, an image subjected to the geometrical change process is projected in the projection area.

Description

  The present invention relates to a technique for displaying a GUI.

  In recent years, a multi-projection system using a combination of a plurality of projectors has been used to display a large screen, high brightness, and high resolution video. The multi-projection system divides and displays a single screen on multiple projectors to increase the screen size and resolution, and the multiple projectors display the same screen at the same location for high brightness. Generalized stack projection systems are common.

  Japanese Patent Application Laid-Open No. H11-228707 proposes GUI screen display control in this multi-projection system. In this case, an image display portion that transmits an image to each projector constituting the multi-projection system manages a GUI screen for each projector. Then, when displaying, an image display part sends a GUI screen corresponding to each projector and combines the displays, thereby making it possible to easily identify an abnormal projector from a plurality of projectors.

Japanese Patent Laid-Open No. 8-079670

  However, the technique described in Patent Document 1 has a problem that the user must remember the identification number of the projector because the projector is identified by the number on the GUI screen. For this reason, when a GUI screen is displayed due to an error or the like on a specific projector during projection with the multi-projection system, there is a problem that the user cannot uniquely determine which projector is displaying.

  The present invention has been made in view of the above problems, and provides a technique for specifying a projector that is uniquely displayed by a user when a menu or an error is displayed on a GUI screen. With the goal.

  In order to achieve the object of the present invention, for example, a projector apparatus of the present invention is a multi-projection system having a plurality of projector apparatuses that project an input original image, and the plurality of projector apparatuses are on a projection area. A projector apparatus in the multi-projection system that forms an image on the projection area by projecting an image, wherein the original image input to the projector apparatus can be changed based on the installation position of the projector apparatus. Calculation means for calculating an installation position of the projector apparatus using some variable parameters used in the case of deformation, an acquisition means for acquiring an installation position of a projector apparatus other than the target projector apparatus, and the calculation means; Using the calculated installation position, the installation position acquired by the acquisition means, Determining means for determining a relative position of the projector apparatus with respect to the projector apparatus and determining a partial area corresponding to the relative position as a GUI display area in the projection area; and displaying the GUI in the original image input to the projector apparatus A synthesis unit that synthesizes a GUI in an area corresponding to the area; and an image obtained by the synthesis unit is subjected to some variable processing using the variable parameters, and the image subjected to the variable processing is obtained. Means for projecting onto the projection area.

  By displaying the GUI screen according to the position of the projector, it is possible to specify the projector that is uniquely displayed by the user when the menu or error is displayed on the GUI screen.

The block diagram which shows the function structural example of a projector apparatus. The figure which shows the example of an external appearance of a multi-projection system. The figure which shows an example of an original image and a projection image. The figure which shows the structural example of a list. The figure which shows the example of a division | segmentation of a projection area | region. The flowchart of the process performed in order to manage a correction parameter. The flowchart of the process performed in order to project the original image by which GUI was synthesize | combined. The figure which shows an example of an original image and a projection target image. The figure which shows the example of an external appearance of a multi-projection system. The figure which shows the structural example of a list. The figure which shows the example of a division | segmentation of a projection area | region. The flowchart of the process performed in order to project the original image by which GUI was synthesize | combined. The figure which shows an example of an original image and a projection target image.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. The embodiment described below shows an example when the present invention is specifically implemented, and is one of the specific examples of the configurations described in the claims.

[First Embodiment]
First, the multi-projection system according to this embodiment will be described. The multi-projection system according to the present embodiment includes a plurality of projector devices that project an input original image onto an appropriate projection surface. The plurality of projector apparatuses project images on the same projection area, thereby forming one screen on the projection area. In the following, one projector apparatus included in the multi-projection system will be described, but the other projector apparatuses perform the same operation.

  In the present embodiment, a stack projection system will be described in which a plurality of projector apparatuses perform image projection on the same projection area to form one screen on the projection area. However, the same operation is performed in a multi-projection system in which image projections are arranged on the projection area to form one screen.

  A functional configuration example of the projector apparatus according to the present embodiment will be described with reference to the block diagram of FIG. The network communication unit 118 performs data communication with an external device via the network 123. The data communication performed by the network communication unit 118 will be described later.

  The image input unit 110 reads an original image from an external device 121 that is a device capable of supplying an image, such as a USB memory, a hard disk drive device, or a PC (personal computer), and supplies the read original image to the image composition unit 111. . When the network communication unit 118 receives an original image from the outside via the network 123, the image input unit 110 acquires the received original image via the control unit 119, and the acquired original image is displayed as an image. The data is sent to the combining unit 111. When the acquired original image is compressed according to a predetermined format, the image input unit 110 decompresses the original image and supplies the decompressed image to the image composition unit 111. Note that the original image acquisition method is not limited to this, and various acquisition methods can be considered.

  The remote controller 122 is a user interface that allows various instructions to be input by a user's operation, and generates a remote control signal corresponding to the input instructions. When receiving the generated remote control signal, remote control light receiving unit 117 converts the remote control signal into a remote control code, and sends the converted remote control code to control unit 119.

  The GUI display control unit 115 acquires data necessary for drawing the GUI and the installation position of each projector device from the memory 120 via the control unit 119. Then, the GUI display control unit 115 determines the layout position of the GUI on the original image using the installation position of each projector device, and generates a GUI image using data necessary for drawing the GUI. Then, the GUI display control unit 115 sends the generated GUI image and the arrangement position of the GUI image to the image composition unit 111.

  When the image composition unit 111 receives the GUI image and the position of the GUI from the GUI display control unit 115, the GUI display control unit 115 determines the GUI image on the original image from the image input unit 110. Composite to the arranged position. Then, the image composition unit 111 sends the original image obtained by compositing the GUI to the image correction unit 112.

  The image correction unit 112 acquires correction parameters from the correction parameter management unit 114, and performs necessary image correction such as focus and keystone on the image from the image synthesis unit 111 using the acquired correction parameters, The image is sent to the image projection unit 113.

  The image projection unit 113 acquires correction parameters from the correction parameter management unit 114, performs lens correction such as lens shift on the image from the image correction unit 112 using the acquired correction parameters, and performs lens correction. An image is projected onto the projection area.

  The correction parameter management unit 114 manages, as the correction parameter, a variable parameter used when the original image input to the projector device 100 is variable according to the installation position of the projector device 100. More specifically, this correction parameter is a parameter for correction performed when displaying an image such as a focus or a keystone according to the installation position of the projector device 100. This correction parameter includes a tilt angle, a projection distance, and a lens shift value, and is determined by an initial setting or a user operation. Further, the correction parameter management unit 114 also manages correction parameters received by the network communication unit 118 from other projector devices.

  The position information detection unit 116 acquires the correction parameter of each projector device from the correction parameter management unit 114, and performs the calculation process described later using the acquired correction parameter of each projector device, thereby determining the installation position of each projector device. calculate. Each correction parameter acquired from the correction parameter management unit 114 and the installation position calculated from the correction parameter are stored in the memory 120 via the control unit 119.

  The control unit 119 performs processing control using the computer program and data stored in the memory 120, thereby controlling the operation of each unit constituting the projector device 100. However, the memory 120 stores information that is explained as being managed by this apparatus and information that is explained as known information.

  An example of the appearance of the multi-projection system according to the present embodiment is shown in FIG. 2, and FIG. 2 shows an example of the appearance of a multi-projection system having four projector apparatuses.

  The four projector apparatuses 201, 202, 203, and 204 project images onto a projection area 205 on the screen. The four projector apparatuses 201, 202, 203, and 204 are connected to the network 123, and are the projector apparatuses 100 having the configuration shown in FIG.

  The apparatus that supplies the original image may be connected to any one of the four projector apparatuses or may be connected via the network 123. When connected to any of the four projector devices, the original image is transmitted from the connected projector device to another projector device other than the projector device via the network 123.

  Next, FIG. 3 shows an example of an original image and an image projected by each of the four projector devices 201, 202, 203, and 204 described above. FIG. 3A shows an example of an original image input to each projector device. FIG. 3B shows a projection target image obtained by the image correction unit 112 correcting the original image shown in FIG. 3A using the correction parameters from the correction parameter management unit 114 in the projector device 201. ing. 3C to 3E show projections obtained by correcting the original image of FIG. 3A using the correction parameters from the correction parameter management unit 114 by the image correction unit 112 of the projector apparatuses 202 to 204, respectively. The target image is shown.

  The four vertices Ao, Bo, Co, and Do in the original image in FIG. 3A are mapped to Ar1, Br1, Cr1, and Dr1 in FIG. 3B by some variable processing using correction parameters. As shown in ArX, BrX, CrX, DrX (X = 1, 2, 3, 4) in FIGS. 3B, 3C, 3D, and 3E, the correction parameter The shape of the image to be displayed is uniquely determined by the difference. However, the installation position of the projector device can be specified from the correction parameter.

  Here, each projector apparatus constituting the multi-projection system acquires and manages not only the correction parameters of the own apparatus but also the correction parameters of other apparatuses. Therefore, processing performed by the projector device 100 for managing correction parameters of the own device and other devices will be described with reference to FIG. 6 showing a flowchart of the processing. Of course, the processing according to the flowchart of FIG. 6 is performed by each projector apparatus constituting the multi-projection system.

  When it is detected that the power of the projector device 100 is turned on, the control unit 119 starts the setting process of the projector device 100. In step S601, the control unit 119 determines whether or not the setting process is completed. to decide. As a result of this determination, if it is not yet completed, the process proceeds to step S602, and if it is completed, the process proceeds to step S603.

  In step S602, the control unit 119 performs a setting process to set correction parameters including a tilt angle, a projection distance, and a lens shift value. The correction parameter may be set according to an operation (remote control code) from the remote controller 122, or may be set by the control unit 119 by some process. Then, the control unit 119 sends the set correction parameter to the correction parameter management unit 114.

  In step S603, the correction parameter management unit 114 determines whether the correction parameter sent from the control unit 119 in step S602 is different from the correction parameter of the projector device 100 that has already been managed. That is, it is determined whether the correction parameter has been changed from the previous one. If the result of this determination is that there has been a change, the process proceeds to step S604, and if there has been no change, the process proceeds to step S605.

  In step S604, the correction parameter management unit 114 registers the correction parameter sent from the control unit 119 in step S602 in a list managed by itself. At that time, the correction parameters of the projector apparatus 100 already registered in the list are overwritten and registered.

  In step S605, the network communication unit 118 transmits the correction parameters set by the control unit 119 in step S602 to other projector devices via the network 123.

  In step S606, the control unit 119 determines whether the network communication unit 118 has received correction parameters set by the projector device in the same manner as the projector device 100 from other projector devices. As a result of this determination, if it has been received, the process proceeds to step S607. If it has not been received, the process returns to step S606 to wait for this reception.

  In step S607, the correction parameter management unit 114 registers the correction parameters of each projector apparatus received by the network communication unit 118 in the above list. Thereby, not only the correction parameters of the projector device 100 but also the correction parameters of other projector devices can be registered in this list.

  In step S607, when the correction parameter of the target projector device is registered in the list, the correction parameter of the target projector device is already registered in the list, and the correction parameter to be registered is the same as the registered correction parameter. . In this case, the correction parameter to be registered may be registered by overwriting the registered correction parameter, or the registration may be canceled. On the other hand, if they are not the same, the correction parameter to be registered is registered in the list as a correction parameter for the new projector device.

  In this way, by performing the processing according to the flowchart of FIG. 6, each projector apparatus constituting the multi-projection system can manage not only the correction parameters of the own apparatus but also the correction parameters of other projector apparatuses. it can.

  Here, FIG. 4 shows a configuration example of a list generated by executing the processing according to the flowchart of FIG. The list 400 of FIG. 4 is created by each projector device when the multi-projection system includes the projector devices 201 to 204 as shown in FIG. 2. Here, the list 400 is created by the projector device 201. The list 400 will be described. Of course, the same description can be applied to lists created by other projector apparatuses.

  The list 400 is for managing correction parameters for each projector number. The projector number is registered in the column 401 of the list 400, the tilt angle is registered in the column 402, and the projection distance is registered in the column 403. In column 404, lens shift values are registered.

  The tilt angle registered in the column 402 is an inclination on the installation surface of the projector device. For example, the tilt angle registered in the row 405 is −30 ° in the vertical direction (vertical direction) θ and 30 ° in the horizontal direction (horizontal direction) φ. Since the tilt angle is set to 0 at the center, depending on the installation position of the projector apparatus, there may be a case where a plus is indicated like the tilt angle registered in the row 407.

  The projection distance registered in the column 403 is a distance between the projector device and the screen surface. For example, the projection distance registered in the row 405 is 300 cm.

  The lens shift value registered in the column 404 is the projection position of the screen by the lens at the time of projection by the projector device. For example, the lens shift value registered in the row 405 is 10% in the vertical direction and 15% in the horizontal direction. Since this lens shift value has a center of 0, depending on the installation position of the projector apparatus, there may be a case where the value is negative like the lens shift value registered in the row 406.

  The correction parameter management unit 114 of each projector apparatus holds a variable j. In the case of FIG. 4, j = 1 when no correction parameter has been received. When receiving the correction parameter, the correction parameter management unit 114 registers the received correction parameter in the list together with the value of the variable j. After registration, the value of this variable j is incremented by 1, and the next correction parameter is waited for. That is, the value of the variable j is used as the projector number.

  When the projector apparatus 201 creates the list 400 according to the flowchart of FIG. 6, the correction parameter of the projector apparatus 201 and the value “1” of the variable j are registered in the row 405. Further, the correction parameter received from the projector device 202 is registered in the row 406 together with the value “2” of the variable j. Further, the correction parameter received from the projector device 203 is registered in the row 407 together with the value “3” of the variable j. The correction parameter received from the projector device 204 is registered in the row 408 together with the value “4” of the variable j. The correspondence relationship between the projector number and the projector device is not limited to this.

  In this way, the correction parameters of each projector apparatus are registered in the list together with the number unique to the projector apparatus. Each numerical value shown in FIG. 4 is an example, and the present embodiment is not specialized for each numerical value. In addition, after the creation of the list 400, each numerical value registered in the list 400 may be edited as appropriate according to user operations and various environments surrounding the multi-projection system.

  After each projector device creates the above list, the input original image is corrected as appropriate and projected onto the projection area. However, when an error occurs in the projector device 100 or an instruction to project a GUI is input. The projector device 100 performs the following processing. A process performed by the projector device 100 to project an original image combined with a GUI will be described with reference to FIG. 7 showing a flowchart of the process.

  In step S701, the control unit 119 determines whether the remote control code received from the remote control light receiving unit 117 is a remote control code indicating that a GUI is newly displayed or an already displayed GUI is updated. As a result of this determination, when the remote control code received from the remote control light receiving unit 117 indicates that a GUI is newly displayed or an already displayed GUI is updated, the process proceeds to step S702. On the other hand, when the remote control code received from the remote control light receiving unit 117 does not indicate that the GUI is newly displayed and does not indicate that the GUI already displayed is updated, the process returns to step S701. .

  In step S702, control unit 119 determines whether the remote control code received from remote control light receiving unit 117 is only for projector device 100 or for each projector device constituting the multi-projection system. That is, it is determined whether or not the remote control code received from the remote control light receiving unit 117 newly displays the GUI only on the projector device 100 or updates the GUI that has already been displayed. As a result of the determination, if the process is for only the projector apparatus 100, the process proceeds to step S703. If the process is for not only the projector apparatus 100 but also each projector apparatus, the process proceeds to step S706.

  In step S703, the GUI display control unit 115 first divides the rectangle having the size of the projection area equally by the number of projector apparatuses included in the multi-projection system. For example, if the multi-projection system is configured as shown in FIG. 2, in step S703, 2 × 2 divided rectangles are generated by dividing the rectangle having the size of the projection area into two vertically and two horizontally. Since the number of projector devices is equal to the maximum number of projector numbers in the list managed by the correction parameter management unit 114, this may be acquired. Note that the method of dividing the projection area is not limited to this.

  In step S704, first, the position information detection unit 116 acquires the correction parameter of each projector device from the correction parameter management unit 114, and obtains the installation position of each projector device using the acquired correction parameter of each projector device. Then, the position information detection unit 116 stores the correction parameter of each projector device acquired from the correction parameter management unit 114 and the installation position calculated from the correction parameter in the memory 120. The series of processing by the position information detection unit 116 may be performed after the creation of the above list instead of this step. A method for obtaining the installation position of the projector apparatus from the correction parameters of the projector apparatus will be described later.

  Next, the GUI display control unit 115 reads the installation positions of the projector devices from the memory 120 via the control unit 119, and specifies the relative positions of the projector device 100 with respect to the other projector devices from the read installation positions. To do. For example, when the multi-projection system is configured as shown in FIG. 2 and the projector apparatus 201 corresponds to the projector apparatus 100, in step S704, the relative position of the projector apparatus 100 is determined as follows. That is, the relative position of the projector device 100 is specified as being on the left side of the projector device 202, directly above the projector device 203, and on the upper left side of the projector device 204.

  Then, the GUI display control unit 115 specifies the divided area at the relative position specified in step S704 among the divided areas divided in step S703 as the divided area corresponding to the projector device 100.

  As described above, when the multi-projection system is configured as shown in FIG. 2, the projection area 501 is divided into 2 × 2 divided rectangles 502 to 505 as shown in FIG. Of the 2 × 2 divided rectangles 502 to 505, the divided rectangle corresponding to the relative position of the projector device 100 is the divided rectangle 502. Thus, it can be seen that the divided rectangle corresponding to the projector device 202 is the divided rectangle 503, the divided rectangle corresponding to the projector device 203 is the divided rectangle 504, and the divided rectangle corresponding to the projector device 204 is the divided rectangle 505.

  In step S705, the GUI display control unit 115 acquires data necessary for rendering the GUI from the memory 120 via the control unit 119, and generates a GUI image using the data necessary for rendering the GUI. To do. Then, the GUI display control unit 115 displays the generated GUI image and an appropriate position in the partial area corresponding to the divided rectangle specified in step S704 (arrangement position of the GUI image). To 111. The “region in the original image corresponding to the divided rectangle specified in step S704” is equivalent to the following. That is, when the original image is equally divided by the number of projector devices included in the multi-projection system as in the division processing in step S703, divided regions corresponding to the relative positions of the projector device 100 among the divided regions. (GUI display area).

  When the image composition unit 111 receives the GUI image and the position of the GUI from the GUI display control unit 115, the GUI display control unit 115 determines the GUI image on the original image from the image input unit 110. Composite to the arranged position. Then, the image composition unit 111 sends the original image obtained by compositing the GUI to the image correction unit 112. Then, the process returns to step S701.

  On the other hand, in step S <b> 706, the image composition unit 111 synthesizes a GUI image at a display position common to the projector apparatuses on the original image, and sends the original image obtained by combining the GUI to the image correction unit 112.

  Next, calculation processing for obtaining the installation position from the correction parameter will be described. First, the arrangement order at the height position of the projector apparatus is calculated from the vertical tilt angle θ, the vertical lens shift value, and the projection distance. The calculation formula is the following formula in which the weight A (constant) is added to the lens shift value.

Height position = (θ + vertical lens shift value × A) × projection distance When this equation is calculated using the correction parameter of the projector device corresponding to projector number 1, (−30 + 0.1A) × 300 is obtained, and A = In the case of 3, (−30+ (0.1 × 3)) × 300 = −8910. When the same calculation is performed for each of the projector devices with projector numbers 2 to 4, the values of the equations are −10517, 7575, and 4242.

  From the tilt angle in the vertical direction and the lens shift value, minus is a position above the center, plus is a position below, and a larger value means that it is farther from the center position. Therefore, from the top, the projector position with projector number 2, the projector apparatus with projector number 1, the projector apparatus with projector number 4, and the projector apparatus with projector number 3 are the height positions. In this way, the relative position of each projector device is determined in the vertical direction.

  The arrangement order in the horizontal position is also calculated from the horizontal tilt angle φ, the horizontal lens shift value, and the projection distance. The calculation formula is the following formula in which the weight B (constant) is added to the lens shift value.

Lateral position = (φ + horizontal lens shift value × B) × projection distance When this equation is calculated using the correction parameter of the projector device corresponding to projector number 1, (30 + 0.15B) × 300, and B = 4 In this case, (30+ (0.15 × 4)) × 300 = 9180. When the same calculation is performed for each of the projector devices with projector numbers 2 to 4, the values of the equations are -5304, 2550, and -4289.6.

  From the tilt angle in the horizontal direction and the lens shift value, minus is a position to the right of the center, and plus is a position to the left. Therefore, from the left, the projector device with the projector number 1, the projector device with the projector number 3, the projector device with the projector number 4, and the projector device with the projector number 2 are in the horizontal position. In this way, the relative positions of the projector devices are determined also in the horizontal direction.

  The relative position of each projector apparatus is determined from the relative position of the projector apparatus at the height position and the horizontal position. That is, it can be specified that the projector device of projector number 1 is located at the upper left, the projector device of projector 2 is located at the upper right, the projector device of projector 3 is located at the lower left, and the projector device of projector 4 is located at the lower right. The above formula and the lens shift value weights A and B are examples, and modifications may be considered as appropriate.

  The correction parameter of each projector device changes depending on the lateral position, height position, distance from the screen, and the like of the installed projector device, and therefore the value is always different unless installed at the same position. Since a plurality of projector devices cannot be installed at the same position, the correction parameter has a different value for each projector device. For this reason, the installation position of each projector apparatus constituting the multi-projection system can be uniquely identified from the correction parameter of each projector apparatus.

  In this embodiment, in the multi-projection system including a plurality of projector devices, the height position and the horizontal position are specified from the correction parameters of each projector device. Judgment is also possible.

  As described above, the list managed by the correction parameter management unit 114 is used for obtaining the relative position between the projector apparatuses. Therefore, the list is used for obtaining the relative position between the projector apparatuses, not the correction parameter. Other information may be registered.

  Here, it is assumed that the multi-projection system is configured as shown in FIG. 2 and that no projector device synthesizes the GUI. In this case, when the original image 801 shown in FIG. 8A is input to the projector device 201, the projector device 201 generates the original image 801 as a projection target image. In FIG. 8, some variable shapes are omitted for the sake of explanation.

  When a GUI is newly displayed only on the projector apparatus 201 or a GUI that has already been displayed is updated, when the original image 801 is input to the projector apparatus 201, the projector apparatus 201 projects the image shown in FIG. Generated as a target image. As shown in FIG. 8B, the GUI 802 is combined in a divided rectangle corresponding to the relative position (upper left) of the projector device 201 on the input original image.

  When a GUI is newly displayed only on the projector apparatus 202 or a GUI that has already been displayed is updated, when the original image 801 is input to the projector apparatus 202, the projector apparatus 202 projects the image shown in FIG. Generated as a target image. As shown in FIG. 8C, on the input original image, a GUI is synthesized in a divided rectangle corresponding to the relative position (upper right) of the projector device 202.

  When a GUI is newly displayed only on the projector apparatus 203 or when an already displayed GUI is updated, when the original image 801 is input to the projector apparatus 203, the projector apparatus 203 projects the image shown in FIG. Generated as a target image. As shown in FIG. 8D, on the input original image, a GUI is combined in a divided rectangle corresponding to the relative position (lower left) of the projector device 203.

  When a GUI is newly displayed only on the projector device 204 or a GUI that is already displayed is updated, when the original image 801 is input to the projector device 204, the projector device 204 projects the image shown in FIG. Generated as a target image. As shown in FIG. 8E, a GUI is combined in a divided rectangle corresponding to the relative position (lower right) of the projector device 204 on the input original image.

  FIG. 8F shows a projection area when each of the projector apparatuses 201, 202, 203, and 204 projects a unique GUI.

  As described above, according to the present embodiment, in the original image, the user uniquely determines the projector device displaying the GUI by synthesizing the GUI in an area corresponding to the relative position of the projector device. It becomes possible.

[Second Embodiment]
Only the differences from the first embodiment will be described below. In the present embodiment, the GUI display size is controlled in accordance with the projection distance included in the correction parameter.

  A configuration example of the multi-projection system according to the present embodiment is shown in FIG. In the multi-projection system according to the present embodiment, two projector apparatuses 901 and 902 project an image within a projection area 903 on the screen. Each of the projector devices 901 and 902 is the projector device 100 described in the first embodiment.

  In the present embodiment, a stack projection system in which two projector apparatuses 901 and 902 project images on the same projection area to form one screen on the projection area will be described. However, the same operation is performed in a multi-projection system in which image projections are arranged on the projection area to form one screen.

  An external device that supplies an image may be connected to any of the projector devices 901 and 902 or may be connected via the network 123. Hereinafter, the multi-projection system according to the present embodiment will be described as having two projector apparatuses 901 and 902 as shown in FIG. However, it is obvious from the following description that the essence of the following description can be applied to a multi-projection system having two or more projector devices regardless of the number of projector devices.

  An example of the list managed by each correction parameter management unit 114 of the projector devices 901 and 902 is shown in FIG. The method of generating the list 1000 by each of the projector devices 901 and 902 is as described in the first embodiment. Each of the projector apparatuses 901 and 902 specifies the relative position of each projector apparatus 901 and 902 from this list, and this specifying process is also as described in the first embodiment. As a result, it can be seen that the projector device (901) with projector number 1 is located in the upper right and the projector device (902) with projector number 2 is located in the lower left. Reference numerals 1001 to 1004 are the same as the above-described 401 to 404, respectively.

  Next, a method in which each position information detection unit 116 of the projector apparatuses 901 and 902 specifies the depth position of each projector apparatus 901 and 902 from the projection distance included in the correction parameter will be described. The depth positions of the respective projector apparatuses 901 and 902 can be specified by comparing the projection distances in the correction parameters of the respective projector apparatuses 901 and 902. Of course, various methods can be considered for this specific method.

  In the case of the projector apparatus 901 having the projector number 1, the projection distance is indicated by the row 1005 in the column 1003 and is 1000 cm. For projector device 902 with projector number 2, the projection distance is indicated by row 1006 in column 1003 and is 260 cm. A larger projection distance means that the depth position from the screen is farther. Therefore, regarding the depth position, the projector device 902 and the projector device 901 are located near the screen.

  The correction parameter of each projector device varies depending on the horizontal position, height position, and depth position from the screen of the installed projector device, and therefore the value is always different unless installed at the same position. Since a plurality of projector devices cannot be installed at the same position, the correction parameter has a different value for each projector device. For this reason, the installation position of each projector apparatus constituting the multi-projection system can be uniquely identified from the correction parameter of each projector apparatus. In the present embodiment, the depth position is specified from the correction parameter of each projector apparatus, but it is also possible to determine the depth position alone.

  Also in this embodiment, since the list 1000 is used to obtain the relative position between the projector apparatuses, the list is not a correction parameter, but other information used to obtain the relative position between the projector apparatuses. You may register.

  Processing performed by the projector device 901 for projecting an original image combined with a GUI will be described with reference to FIG. 12 showing a flowchart of the processing. The process according to the flowchart of FIG.

  In step S1201, the control unit 119 determines whether or not the remote control code received from the remote control light receiving unit 117 is a remote control code indicating that a GUI is newly displayed or an already displayed GUI is updated. As a result of the determination, if the remote control code received from the remote control light receiving unit 117 indicates that a GUI is newly displayed or an already displayed GUI is updated, the process proceeds to step S1202. On the other hand, if the remote control code received from the remote control light receiving unit 117 does not indicate that the GUI is newly displayed and does not indicate that the GUI already displayed is updated, the process returns to step S1201. .

  In step S1202, control unit 119 determines whether the remote control code received from remote control light receiving unit 117 is only for projector device 901 or for each projector device constituting the multi-projection system. That is, it is determined whether or not the remote control code received from the remote control light receiving unit 117 newly displays the GUI only on the projector device 901 or updates the already displayed GUI. As a result of the determination, if the process is for only the projector apparatus 901, the process proceeds to step S1203. If the process is for not only the projector apparatus 901 but also each projector apparatus, the process proceeds to step S1207.

  In step S1203, the GUI display control unit 115 equally divides a rectangle having the size of the projection area by the number of projector apparatuses included in the multi-projection system, as in the first embodiment.

  In step S1204, the position information detection unit 116 acquires the correction parameter of each projector device from the correction parameter management unit 114 as described above, and compares the projection distance in the acquired correction parameter. Thereby, the depth relationship of each projector device (which device is positioned in front (back) from which device) is specified. Then, the size of the GUI displayed by the projector device located farther from the screen is set smaller than the size of the GUI displayed by the projector device located closer to the screen.

  That is, if the projection distance in the correction parameter used in the projector apparatus 901 is d1, the projection distance in the correction parameter used in the projector apparatus 902 is d2, and if d1> d2, the size of the GUI is reduced to be smaller than the prescribed size. . On the other hand, when d1 <d2, the size of the GUI is scaled larger than the prescribed size.

  In the case of FIG. 9, since the projector device 901 is farther from the screen than the projector device 902, the size of the GUI displayed by the projector device 901 is set smaller than the size of the GUI displayed by the projector device 902. For example, when the size defined as the normal size is 1, the size of the GUI displayed by the projector device 901 is 0.8, and the size of the GUI displayed by the projector device 902 is 1.2. Of course, the size is not limited to this.

  In step S1205, as in the first embodiment, the position information detection unit 116 obtains the installation position of each projector apparatus, and stores the correction parameter of each projector apparatus and the installation position calculated from the correction parameter in the memory 120. To store. Also in the present embodiment, the series of processing by the position information detection unit 116 may be performed after the creation of the list, not in this step.

  Next, the GUI display control unit 115 specifies the relative position of the projector device 901 with respect to the projector device 902 in the same manner as in the first embodiment. Then, the GUI display control unit 115 specifies the divided area at the relative position specified in step S1205 among the divided areas divided in step S1203 as the divided area corresponding to the projector device 901.

  When the multi-projection system is configured as shown in FIG. 9, the projection area 1101 is divided into two divided rectangles 1102 and 1103 as shown in FIG. Of the two divided rectangles 1102 and 1103, the divided rectangle corresponding to the relative position of the projector device 901 is the divided rectangle 1103, and the divided rectangle corresponding to the relative position of the projector device 902 is the divided rectangle 1102. . Of course, the method of dividing the area is not limited to this.

  In step S1206, the GUI display control unit 115 acquires data necessary for rendering the GUI from the memory 120 via the control unit 119, and generates a GUI image using the data necessary for rendering the GUI. To do. At this time, the GUI display control unit 115 changes the size of the generated GUI image to the size set in step S1204. Then, the GUI display control unit 115 performs image synthesis on the GUI image after scaling and an appropriate position (arrangement position of the GUI image) in the area in the original image corresponding to the divided rectangle specified in step S1205. Sent to the unit 111.

  When the image composition unit 111 receives the GUI image and the position of the GUI from the GUI display control unit 115, the GUI display control unit 115 determines the GUI image on the original image from the image input unit 110. Composite to the arranged position. Then, the image composition unit 111 sends the original image obtained by compositing the GUI to the image correction unit 112. Then, the process returns to step S1201.

  On the other hand, in step S1207, as in the first embodiment, the image composition unit 111 synthesizes a GUI image at a common display position between projector devices on the original image, and the original image obtained by combining the GUI is an image correction unit. 112.

  Here, it is assumed that the multi-projection system is configured as shown in FIG. 9, and no projector device synthesizes the GUI. In this case, when the original image 1301 shown in FIG. 13A is input to the projector device 901, the projector device 901 generates the original image 1301 as a projection target image. In FIG. 13, some variable shapes are omitted for the sake of explanation.

  When a GUI is newly displayed only on the projector device 901 or a GUI that has already been displayed is updated, when the original image 1301 is input to the projector device 901, the projector device 901 projects the image shown in FIG. Generated as a target image. As shown in FIG. 13B, a GUI 1302 is synthesized in a divided rectangle corresponding to the relative position (upper right) of the projector device 901 on the input original image. As described above, since the projector device 901 is farther from the projection area than the projector device 902, the size of the GUI displayed by the projector device 901 is smaller than the normal size.

  When a GUI is newly displayed only on the projector device 902 or an already displayed GUI is updated, when the original image 1301 is input to the projector device 902, the projector device 902 projects the image shown in FIG. Generated as a target image. As shown in FIG. 13C, the GUI 1303 is synthesized in the divided rectangle corresponding to the relative position (lower left) of the projector device 902 on the input original image. As described above, since the projector device 902 is closer to the projection area than the projector device 901, the size of the GUI displayed by the projector device 902 is larger than the normal size.

  FIG. 13D shows a projection area when each of the projector apparatuses 901 and 902 projects a unique GUI. As described above, since the projector device 901 is farther from the projection area than the projector device 902, the size of the GUI displayed by the projector device 901 is smaller than the size of the GUI displayed by the projector device 902.

  As described above, according to the present embodiment, it is possible to newly determine and display the GUI size reflecting the projection distance in the correction parameter.

[Third Embodiment]
One or more of the units other than the control unit 119 and the memory 120 illustrated in FIG. 1 may be configured by hardware, but may be implemented by software (computer program). In this case, this software is stored in the memory 120 and executed by the control unit 119.

  Moreover, you may combine each above embodiment suitably. In the above embodiment, the information transmitted / received between the projector apparatuses is a correction parameter. However, the installation position (the depth value in the second embodiment in addition to this in the second embodiment) calculated by the own apparatus may be transmitted to another apparatus. In this case, as a matter of course, the projector apparatus that has received the installation position of the other apparatus does not need to calculate the installation position of the other apparatus. Further, instead of the correction parameter used in each of the above-described embodiments, the position data of the vertex after the mapping calculated from the correction parameter may be used.

(Other examples)
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

Claims (7)

A multi-projection system having a plurality of projector devices for projecting an input original image, wherein the plurality of projector devices project an image on the projection region, thereby forming one screen on the projection region. A projector device in a multi-projection system,
Calculating means for calculating the installation position of the projector apparatus using some variable parameters used when the original image input to the projector apparatus is made variable depending on the installation position of the projector apparatus;
Obtaining means for obtaining an installation position of another projector device other than the projector device;
Using the installation position calculated by the calculation unit and the installation position acquired by the acquisition unit, a relative position of the projector device with respect to the other projector device is specified, and a partial region corresponding to the relative position in the projection region Determining means for determining as a GUI display area;
Synthesizing means for synthesizing the GUI in an area corresponding to the GUI display area in the original image input to the projector device;
Means for performing variable deformation processing on the image obtained by the synthesizing means using the variable variable parameter, and projecting the image subjected to the variable deformation processing to the projection region. Projector device.   The projector device according to claim 1, wherein the acquisition unit acquires the installation position of the other projector device calculated by the calculation unit of the other projector device transmitted from the other projector device. .   2. The acquisition unit according to claim 1, wherein the acquisition unit acquires the installation position by calculating an installation position of the other projector apparatus using some variable parameters transmitted from the other projector apparatus. Projector device. The calculation means includes a vertical tilt angle θ of the projector device, a vertical lens shift value, a projection distance from the projector device to the projection area, which are included in some variable parameters used in the projector device. And calculate (θ + vertical lens shift value × constant) × projection distance as the height position of the projector device,
The acquisition means includes the vertical tilt angle θ of the other projector device, the vertical lens shift value, the projection area from the other projector device, which are included in the variable parameters used in the other projector device. (Θ + vertical lens shift value × constant) × projection distance is calculated as the height position of the other projector device using
The determining means uses the height position of the projector device and the height position of the other projector device to identify the relative position in the vertical direction of the projector device with respect to the other projector device,
The calculation means includes a horizontal tilt angle φ of the projector device, a horizontal lens shift value, a projection distance from the projector device to the projection area, which are included in some variable parameters used in the projector device. (Φ + horizontal lens shift value × constant) × projection distance is calculated as the lateral position of the projector device,
The acquisition means includes a horizontal tilt angle φ, a horizontal lens shift value of the other projector device, a projection area from the other projector device, which are included in some variable parameters used in the other projector device. (Φ + lens shift value in the horizontal direction × constant) × projection distance is calculated as the lateral position of the other projector device using
The determination unit specifies a relative position in a horizontal direction of the projector device with respect to the other projector device using a horizontal position of the projector device and a horizontal position of the other projector device. 3. The projector device according to 3. The synthesis means includes
The projection distance from the projector device included in the variable parameter used in the projector device to the projection area is d1, from the other projector device included in the variable parameter used in the other projector device. The projection distance to the projection area is d2,
In the case of d1> d2, the size of the GUI is scaled to be smaller than a prescribed size, and the scaled GUI is placed in an area corresponding to the GUI display area in the original image input to the projector device. Synthesize,
When d1 <d2, the size of the GUI is scaled larger than a prescribed size, and the scaled GUI is placed in an area corresponding to the GUI display area in the original image input to the projector device. The projector device according to claim 1, wherein the projector device is combined.   The determination unit divides the projection area into divided areas corresponding to the number of projector apparatuses included in the multi-projection system, and positions of the divided areas according to relative positions of the projector apparatus with respect to the other projector apparatuses. 6. The projector according to claim 1, wherein a divided area is determined as the GUI display area. A multi-projection system having a plurality of projector devices for projecting an input original image, wherein the plurality of projector devices project an image on the projection region, thereby forming one screen on the projection region. A method for controlling a projector device in a multi-projection system,
The calculation means of the projector apparatus calculates the installation position of the projector apparatus using some variable parameters used when the original image input to the projector apparatus is deformed several times based on the installation position of the projector apparatus. A calculation process to
The acquisition unit of the projector device acquires an installation position of a projector device other than the projector device; and
The determination unit of the projector device specifies a relative position of the projector device with respect to the other projector device using the installation position calculated in the calculation step and the installation position acquired in the acquisition step, and in the projection region A determination step of determining a partial area corresponding to the relative position as a GUI display area;
A synthesizing step in which the synthesizing unit of the projector apparatus synthesizes the GUI in an area corresponding to the GUI display area in the original image input to the projector apparatus;
Projection means of the projector device performs variable deformation processing on the image obtained in the combining step using the variable parameter, and projects the variable image to the projection area. And a projector device control method comprising: a step of:

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