JP2010164981A - Image transfer device, and image display control method in image transfer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To project a desired content to each of a plurality of image projectors, with respect to the plurality of contents on a display screen, and to enhance the convenience of an operation for the projected content. <P>SOLUTION: An image transfer device displays layout display windows W2L and W3L within a layout display area LA, as to windows W2 and W3 on a primary screen, corresponding to a displaying image data transferred to the projector. The layout of an image projected by the projector is changed corresponding to the layout-regulated layout display window, when a layout regulation operation, such as, position movement or size change is executed with respect to the layout display windows W2L and W3L within the layout display area LA. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image transfer apparatus and an image display control method in the image transfer apparatus.

  The image projection apparatus is used by being connected to an image transfer apparatus, for example, a personal computer, for example, in order to project presentation content onto a projection surface. A conventional image transfer apparatus generates display image data by using a display screen of a display device as a unit, and displays an image on the display device using the generated display image data. Therefore, when displaying an image displayed on the display device using the image projection device, the display image data is transferred to the image projection device, so that some content on the display screen, for example, an announcement It was not possible to meet the demand for displaying only the content for the presentation of the person himself.

  On the other hand, a technique for outputting window data of a window selected by a mouse pointer from a plurality of windows displayed on a display device to an external monitor is known (for example, Patent Document 1).

JP 2000-339130 A

  However, when a plurality of image projection devices are connected to the image transfer device, it is impossible to transfer a plurality of contents displayed on the display device to desired image projection devices. In addition, for content in which a part of the content is displayed on the display device, the entire content cannot be projected via the image projection device.

  This problem is not limited to an image transfer apparatus to which a plurality of image projection apparatuses are connected, but is a problem common to image transfer apparatuses to which a plurality of external display apparatuses are connected.

  SUMMARY An advantage of some aspects of the invention is to solve at least a part of the above-described problems by causing a plurality of image projection apparatuses to project desired contents for a plurality of contents on a display screen, and for the projected contents. The purpose is to improve the convenience of operation.

  In order to solve at least a part of the above problems, the present invention adopts the following various aspects.

  A first aspect of the present invention provides an image transfer device to which a plurality of image projection devices can be connected. According to a first aspect of the present invention, there is provided a display capable of displaying a plurality of contents, a display image data generating section for generating display image data of each content at least partially displayed on the display, A storage device that stores the display image data at a storage position that is associated with a projection position of an image by the image projection device, each of the connected image projection devices, and each of the generated display image data Are stored in the storage device in association with each other, a transfer unit that transfers the associated display image data to each image projection device, and the display image data. And displaying a plurality of layout display images corresponding to each display image data transferred to each image projection apparatus on the display. And a display control unit for displaying on 示領 region.

  According to the first aspect of the present invention, each connected image projection device and each generated display image data are stored in the storage device in association with each other, and each image projection device is associated with each other. Since each display image data is transferred, desired contents can be projected on a plurality of image projection apparatuses for a plurality of contents on the display screen. In addition, since a plurality of layout display images corresponding to each display image data transferred to each image projection apparatus can be displayed in the layout display area on the display, it is convenient to operate the projected content. Can be improved.

  In the first aspect of the present invention, when an operation is performed on the layout display image, the display image data corresponding to the layout display image on which the operation is performed is applied. An image processing unit that executes image processing that reflects the operation performed may be provided. In this case, the operation on the image projected from the image projection apparatus can be executed by the operation on the layout display image.

  In the first aspect of the present invention, the operation is an operation of changing a size of the layout display image, and the image processing unit converts the resolution of the display image data according to the change of the size, and The transfer unit may transfer the display image data subjected to the image processing to the corresponding image projection apparatus. In this case, the size of the image projected from the image projection apparatus can be changed by a size change operation on the layout display image.

  In the first aspect of the present invention, the display control unit may display an image whose size has been changed on the display device, using the display image data subjected to the image processing. In this case, the image after the size change can be confirmed on the display.

  1st aspect of this invention WHEREIN: The said operation is operation which changes the display position of the said layout display image, The said image process part is the said display image data in the said memory | storage device according to the change of the said display position. The transfer unit may transfer the display image data subjected to the image processing to the corresponding image projection apparatus. In this case, the projection position of the image projected from the image projection apparatus can be changed by an operation of changing the display position with respect to the layout display image.

  The first aspect of the present invention further specifies a selection unit for selecting one content from among a plurality of contents displayed on the display device, and an image projection apparatus for projecting the selected content. The storage controller may store the selected display image data and the specified image projection apparatus in the storage device in association with each other. In this case, the selected content can be associated with the designated image projection apparatus.

  In the first aspect of the present invention, the storage control unit secures a content storage area for storing the display image data in the storage device in accordance with the number of contents displayed on the display. The display image data may be stored in a storage position associated with an image projection position by the image projection apparatus in each content storage area. In this case, by associating the storage area for storing the content displayed on the display device with the image projection apparatus, it is possible to project desired contents on each of the plurality of image projection apparatuses. Moreover, the projection position of the image by the image projection apparatus can be changed by changing the storage position.

  In the first aspect of the present invention, the image processing unit may perform image processing on the image data in the content storage area. In this case, image processing can be executed on a content basis.

  1st aspect of this invention WHEREIN: The said storage control part sets the memory area for transfer for storing the said image data for a display for transferring to the said image projection apparatus to the number of the said image projection apparatuses connected. Accordingly, the display image data may be secured in the storage device and stored in a storage position associated with a projection position of the image by the image projection device in each of the transfer storage areas. In this case, by transferring the display image data from the storage device associated with the image projection apparatus to the image projection apparatus, it is possible to project desired contents on each of the plurality of image projection apparatuses.

  In the first aspect of the present invention, the image processing unit may perform image processing on the image data in the transfer storage area. In this case, image processing can be executed in units of image projection apparatuses.

  In the first aspect of the present invention, the content storage area is secured in correspondence with the arrangement of the connected image projection apparatuses, and the storage control unit has a capacity of the display image data that is stored in the content storage. When the capacity of the area is exceeded, the display image data is stored in a plurality of content storage areas corresponding to the adjacent image projection apparatuses, and the display control unit displays a layout display corresponding to the display image data An image may be displayed over a plurality of adjacent layout display areas. In this case, it is possible to store the display image data of one window partially displayed on the display device across multiple storage areas, and grasp the layout of the window in the layout display area. can do. Furthermore, the window can be projected by a plurality of image projection apparatuses.

  In the first aspect of the present invention, the layout display area may have the same aspect ratio as the display screen of the display. In this case, the outer shape of the display image on the display device and the image projected by the image projection device can be matched.

  In the first aspect of the present invention, the display control unit changes the overlapping order of the plurality of layout display images in the layout display area in accordance with an operation for changing the overlapping order of the plurality of layout display images. It may be changed. In this case, the overlapping order of the layout display images can be changed.

  A second aspect of the present invention provides an image display control method in image transfer. According to a second aspect of the present invention, display image data of each content at least a part of which is displayed on a display is generated, each connected image projection apparatus, and each of the generated display image data Are stored in a storage device, the display image data corresponding to the image projection devices are transferred to the image projection devices, and the display images are transferred to the image projection devices. Displaying a plurality of layout display images corresponding to image data in a layout display area on the display.

  According to the second aspect of the present invention, advantages similar to those of the first aspect of the present invention can be obtained. The second aspect of the present invention can be implemented in various aspects in the same manner as the first aspect of the present invention. Furthermore, the second aspect of the present invention can also be realized as a computer program recorded on a computer-readable medium such as a computer program, CD, DVD, or HDD.

It is explanatory drawing which shows schematic structure of the image transfer system containing the image transfer apparatus which concerns on a present Example. 3 is a functional block diagram schematically illustrating an internal configuration of the image transfer apparatus according to the embodiment. FIG. It is a functional block diagram which shows typically the internal structure of the image projection apparatus used in a present Example. It is a flowchart which shows the process routine performed in the image transfer process performed by the image transfer apparatus which concerns on a present Example. It is explanatory drawing which shows an example of the screen on the display display on which a some window is displayed. It is explanatory drawing which shows the example of a change of the image on a projector corresponding to the moved window in FIG. It is explanatory drawing which shows an example of the correspondence of the window storage area which stores the image data for a display, and the storage area for projector transfer. It is explanatory drawing which shows an example of the table which matches the window storage area which stores the image data for a display, the storage area for projector transfer, and a window. It is a flowchart which shows the process routine performed with respect to the layout operation in a present Example. It is explanatory drawing which shows the other example of the screen on the display display on which a some window is displayed. It is explanatory drawing which shows the example of a change of the image on a projector corresponding to the window from which the size was changed in FIG. It is explanatory drawing which shows typically the memory area of RAM which stores the image data for a display of each window shown by FIG. It is explanatory drawing which shows an example of the table which stores a corresponding relationship between a projector and a window.

  Hereinafter, an image transfer apparatus and an image transfer method according to the present invention will be described based on embodiments with reference to the drawings.

First embodiment:
Configuration of Image Transfer System FIG. 1 is an explanatory diagram showing a schematic configuration of an image transfer system including an image transfer apparatus according to the first embodiment. FIG. 2 is a functional block diagram schematically showing the internal configuration of the image transfer apparatus according to the first embodiment. FIG. 3 is a functional block diagram schematically showing the internal configuration of the image projection apparatus used in the first embodiment.

  The image transfer system 10 includes an image transfer device 20 and an image projection device 30. A plurality of image projection devices 30 are connected to the image transfer device 20. The image transfer device 20 and the image projection device 30 are connected via, for example, a universal serial bus (USB) cable CV and a wireless local area network (LAN).

・ Configuration of image transfer device:
The image transfer apparatus 20 is a personal computer, for example, and is connected to an input device 41 such as a display 40, a keyboard, and a mouse. As shown in FIG. 2, the image transfer apparatus 20 includes a central processing unit (CPU) 200, a random access memory (RAM) 210, a hard disk drive (HDD) 220, a drawing memory (VRAM) 230, and an input / output interface 240. ing. The CPU 200, RAM 210, HDD 220, VRAM 230, and input / output interface 240 are connected via a common bus 250 so that bidirectional communication is possible.

  The CPU 200 is a logic circuit that executes various arithmetic processes. For example, the CPU 200 loads and executes various programs and modules stored in the HDD 220 in the RAM 210. A RAM 210 is a volatile memory, and temporarily stores calculation results of the CPU 200 and display image data to be transferred to the image projection apparatus 30. The VRAM 230 is a memory for expanding and temporarily buffering display image data drawn based on the data, and generally allows reading and writing of data at a higher speed than the RAM 210.

  The HDD 220 is a magnetic disk storage device that stores the image transfer program P1. Note that a nonvolatile semiconductor memory may be provided instead of the HDD 220. The image transfer program P1 stored in the HDD 220 includes a window selection module M1, a projector designation module M2, a storage control module M3, a display image data generation module M4, an image processing module M5, a communication control module M6, and a projector information acquisition module M7. And a connected projector management module M8 and a display control module M9. Each module implements various functions by being executed by the CPU 200.

  The image transfer program P1 is a program for transferring an image displayed on the display 40 connected to the image transfer apparatus 20 to an external image output device. More specifically, the image transfer program P1 in the present embodiment can transfer a plurality of contents displayed on the display 40 to each image output device in units of contents. Here, the content is a display screen provided in application units, each document creation screen in word processor software, each presentation screen in presentation software, a playback screen for playing streamed video content, and still image editing Includes screens and display screens. In addition, the so-called desktop screen displayed as the background of the display 40 is also included in the content. Note that these contents are also referred to as windows when Windows (registered trademark) is used as an operating system.

  The window selection module M1 is a module executed to select a desired window from among a plurality of windows displayed on the display display 40. Specifically, the window selected from the plurality of windows by the operator via the input device 41 is specified. For example, by assigning a unique number to a window (open window) displayed on the display 40, each window can be identified and the selected window can be specified.

  The projector designation module M2 is a module for designating the projector (image projection apparatus) 30 that outputs the window selected by the window selection module M1.

  The storage control module M3 is a module for associating the selected window with the designated projector 30 and storing them in the RAM 210 or the HDD 220. The storage control module M3 also stores the RAM 210 in advance according to the number of windows at least partially displayed on the display 40, the number of projectors 30 connected to the image transfer apparatus 20, and the maximum resolution of the display 40. A window storage area (content storage area) for storing window display image data is secured above. Note that at least one of a window storage area corresponding to the number of windows and a transfer storage area corresponding to the number of projectors 30 may be secured in the RAM 210 or the HDD 220.

  The display image data generation module M4 is a module for generating display image data for each window displayed on the display 40. The display image data generation module M4 is a window that exists on the display display 40, in other words, a window that is hidden behind another window, or a window that is not partially displayed beyond the display screen of the display display 40. For the above, display image data can be generated for all of the windows. In this process, for example, not only in the window being operated (active window) but also in other windows, display image data is once drawn on the VRAM 230 at the time of selection, and the drawn display image data is stored in the RAM 210. This is realized by storing in a predetermined position. In this case, whenever a window other than the active window is selected, the display of the other window can be updated by executing the drawing process for the other window. Alternatively, when the capacity of the VRAM 230 is large, display image data for a plurality of windows may be stored on the VRAM 230.

  The image processing module M5 is a module for executing various image processes on the display image data transferred to the projector 30. Image processing executed by the image processing module M5 includes, for example, image processing such as resolution conversion processing, sharpness, luminance adjustment, and color balance. Furthermore, in the present embodiment, in order to transmit to the image projection apparatus 30 in accordance with various operations on the layout display window displayed in the layout display area on the display 40, for example, movement and deformation (resizing). The process of changing the display image data is executed. Specifically, the projection position of the image projected by the image projection apparatus is moved in response to the movement operation on the layout display window, and the image projected by the image projection apparatus is deformed in response to the deformation operation on the layout display window. Let

  The communication control module M6 is a module that controls the input / output interface 240 in order to transfer display image data to the projector 30 or to receive projector information from the projector 30.

  The projector information acquisition module M7 is a module for acquiring projector information I33 (see FIG. 3) from the projector 30. The projector information I33 includes, for example, the maximum resolution supported by the projector, the projector color profile (for example, ICC profile), identification information for specifying the projector, and other information related to the image reproduction characteristics of the projector.

  The connected projector management module M8 is a module for managing the number of projectors 30 connected to the image transfer device 20, that is, the attachment / detachment of the projector 30 with respect to the image transfer device 20.

  The display control module M9 is a module for displaying an image using display image data on the display 40 and displaying a layout display area and a layout display window in a predetermined area on the display 40. The display control module M9 also changes the display of the layout display window based on an operation on the layout display window, for example, movement or deformation (resizing). The display control module M9 also changes the size of the window displayed on the display 40 when the operation on the layout display window is modified (resizing). Further, the display control module M9 displays a plurality of layout display areas for a layout display window of a window that protrudes from the screen of the display display 40, and displays a plurality of layouts including a portion that protrudes from the screen of the display display 40. Display over the working area.

  The input / output interface 240 exchanges signals between the image transfer apparatus 20 and an external device such as the image projection apparatus 40 by wire or wirelessly. In the case of wired, for example, a USB cable connection terminal is provided, and in the case of wireless, for example, a transmission / reception unit including an antenna and a switch for switching transmission / reception is provided. By providing the transmission / reception unit, an antenna access point (AP) function or a station (STA) function for transmitting and receiving transmission / reception signals is realized. The input / output interface 240 also receives an input signal from the input device 41 such as a keyboard and a mouse, and outputs display image data to the display 40.

・ Configuration of image projector:
As described above, the image projection device 30 is, for example, a projector. As shown in FIG. 2, the projector 30 includes a central processing unit (CPU) 300, a random access memory (RAM) 310, a nonvolatile memory (ROM) 320, a drawing memory (VRAM) 330, an image display unit 340, an optical system. 350 and an input / output interface 360. The CPU 300, RAM 310, ROM 320, VRAM 330, image display unit 340, and input / output interface 360 are connected via a common bus 370 so that bidirectional communication is possible.

  The CPU 300 is a logic circuit that executes various arithmetic processes. For example, various programs and modules stored in the ROM 320 are developed on the RAM 310 and executed. The RAM 310 is a volatile memory and temporarily stores the calculation result of the CPU 300. The VRAM 330 is a memory for temporarily buffering drawing data drawn based on display image data.

  The ROM 320 is a semiconductor memory that stores a projector information transmission module M31, a drawing module M32, and projector information I33. Instead of the ROM 320, a magnetic disk storage device may be used.

  The projector information transmission module M31 is a module for transmitting stored projector information to the image transfer apparatus 20. For example, when a wired or wireless connection is established between the projector 30 and the image transfer device 20, the stored projector information I 33 is acquired, and the projector is connected to the image transfer device 20 via the input / output interface 360. The information I33 is transferred.

  The drawing module M32 analyzes the display image data received from the image transfer apparatus 20 via the input / output interface 360 and draws it on the VRAM 330. Specifically, the drawing module M32 analyzes the received display image data, acquires information such as the number of colors, size (vertical and horizontal), coordinates, and image format, and uses the acquired information on the VRAM 330. For example, pixel values are arranged by a bitmap method.

  The image display unit 340 is used to generate an image for projection using the drawing data stored in the VRAM 330. As the image display unit 340, for example, an image display unit that modulates light from an RGB light source using a liquid crystal panel or an image display unit that modulates light using a digital micromirror device (DMD) can be used.

  The optical system 350 includes a plurality of lenses, and is used to project an image generated by the image display unit 340 onto a projection surface with a desired size.

・ Image transfer processing:
FIG. 4 is a flowchart illustrating a processing routine executed in the image transfer process executed by the image transfer apparatus according to the first embodiment. FIG. 5 is an explanatory diagram showing an example of a screen on a display on which a plurality of windows are displayed. FIG. 6 is an explanatory diagram showing an example of an image change on the projector corresponding to the moved window in FIG. FIG. 7 is an explanatory diagram showing an example of the correspondence between the window storage areas A1 to A3 for storing display image data and the projector transfer storage areas SPJ1 to SPJ3. FIG. 8 is an explanatory diagram showing an example of a table that associates window storage areas A1 to A3 for storing display image data, projector transfer storage areas SPJ1 to SPJ3, and windows W1 to W3.

  This processing routine is started, for example, by starting an image transfer application. The CPU 200 executes the projector information acquisition module M7, and acquires projector information I33 from each projector 30 connected to the image transfer device 20 (step S100). Specifically, CPU 200 transfers a projector information transmission request to each wired and wireless port, and transmits a projector information transmission request to each connected projector 30. In each projector 30 that has received the projector information transmission request, the CPU 300 executes the projector information transmission module M31, acquires the projector information I33 from the ROM 320, and returns it to the image transfer apparatus 20. The CPU 200 that has received the projector information uses the projector information acquired from each projector 30 to associate the maximum supported resolution, color profile, identification information, and other image reproduction characteristics of each projector 30 with each projector 30 in the HDD 220. Store.

  The CPU 200 executes the connected projector management module M8, specifies the number of projectors 30 connected to the input / output interface 240, executes the storage control module M3, and corresponds to the number of projectors 30 connected. Then, a projector transfer storage area is secured on the RAM 210 or the HDD 220 (step S110). In the example of FIG. 7, projector transfer storage areas SPJ1 to SPJ3 are secured (assigned) to the projectors PJ1 to PJ3, respectively. For example, the CPU 200 detects the number of wired and wireless ports to which the projector 30 is connected based on the voltage change of the detection power supply terminal at the USB terminal and the detection of connection establishment in wireless communication. Is executed. Note that the projector transfer storage areas SPJ1 to SPJ3 do not necessarily have to be consecutive, unlike the window storage areas A1 to A3 for storing display image data. The projector transfer storage areas SPJ1 to SPJ3 have a capacity corresponding to the resolution of the primary display (desktop screen) of the display 40 for display.

  The CPU 200 executes the storage control module M3 to secure a window storage area corresponding to the number of windows on the RAM 210 (step S120). For example, in Windows (registered trademark), each window is managed by a number called a handle, and is displayed (opened) on the display 40 by the CPU 200 executing the API function “EnumWindows”. You can get the handles of all windows. Therefore, the CPU 200 secures a plurality of window storage areas necessary for storing all windows in the RAM 210 according to the acquired number of handles. In addition, the capacity | capacitance according to the resolution of the desktop screen (primary display) of the display display 40 is ensured as the capacity | capacitance of each window storage area.

  The CPU 200 executes the display image data generation module M4 to generate (capture) display image data for all windows displayed on the display 40 (step S130). In the example of FIG. 5, three windows W <b> 2 to W <b> 4 are displayed on the display 40 in addition to the desktop window W <b> 1. These three windows W2 to W4 can be said to be contents provided by an application. If a part of the window protrudes from the display 40, the protruding part is not displayed on the display 40, but display image data for the entire window including the protruding part is generated. Further, the protruding portion includes both the case where the position of the window is offset and the case where the entire window does not fit on the display display 40. In the former case, the generated display image data can be stored in one window storage area. In the latter case, the generated display image data is stored across a plurality of window storage areas. Is done.

  For example, when the operating system is Windows (registered trademark), display image data corresponding to all windows displayed on the display 40 is generated by forming a layered window. The CPU 200 uses the handle of each window acquired in advance, and the layered setting API “WS_EX_LAYERED” is used for the current window style acquired by “GetWindowLong” and “GetWindowLong” which are API functions for acquiring the setting value of the current window. Each of the windows is formed into a layered window by sequentially executing an API function “SetWindowLong” for registering “OR” and an API function “SetLayeredWindowAttributes” for setting the layered parameter of the designated window. In each layered window, the entire window is captured, that is, display image data corresponding to the entire window is generated.

  The display image data generation module M4 generates display image data by developing (drawing) display image data on the VRAM 230 based on application data corresponding to each window. Each of the generated display image data is sequentially transferred and stored in the window storage area previously secured on the RAM 210. In FIG. 7, the display image data for the window W2 is stored in the first window storage area A1, and the display image data for the window W3 is stored in the second window storage area A2. In this embodiment, the storage control module M3 manages the window storage areas A1 to A3 using the coordinates (X, Y). For example, a window (display image data) on the display screen of the display display 40 is used. Are managed with reference to the upper left coordinates. In addition, the projection position of the image with respect to the projection frame when projected corresponds to the storage position of the display image data stored in each window storage area, and by specifying the coordinates in each window storage area, The position of the projected image can be specified. Each pixel data constituting the display image data can also be specified using coordinates applied to the window storage area.

CPU 200 executes projector designation module M2 and waits for the designation of projector 30 by the user (step S140: No). The designation of the projector 30 is, for example,
By listing all windows present on the display 40 and associating each window with a projector via the input device 41, or
This can be realized by displaying a button for selecting a projector on the title bar of the window and designating a desired projector from a projector selection menu displayed by pressing the button.

  When the projector 30 to be associated with one window is designated (step S140: Yes), the CPU 200 executes the storage control module M3 and associates the designated projector 30 with the selected window (step S140). Specifically, the storage control module M3 is executed to associate the window storage area for storing the display image data corresponding to the selected window with the projector transfer storage area corresponding to the designated projector. The selected window and the designated projector are associated with each other until the user inputs an end of association via the input device 41, until all the windows are associated with the projector, or with all the projectors. (Step S160: No).

  In the example of FIGS. 7 and 8, the display image data for the window W2 is stored in the first window storage area A1 for storing the display image data, and the display image data for the window W3 is stored in the second window storage area A2. Are stored. Further, the first projector PJ1 and the window W1, the second projector PJ2 and the window W2, and the third projector PJ3 and the window W3 are associated with each other.

  The CPU 200 executes the storage control module M3, and the projector transfer storage area SPJ2 which is a storage area for transferring the display image data of the window W2 stored in the first window storage area A1 to the second projector PJ2. Copy or move to. Similarly, the display image data of the window W3 stored in the second window storage area A2 is copied or moved to the projector transfer storage area SPJ3. The association between each projector PJ1 to PJ3 and each storage area is, for example, the port number to which each projector PJ1 to PJ3 is connected or the MAC address of each projector PJ1 to PJ3 (communication control module) and each storage area. This can be realized by associating coordinate information to be defined.

  When the association between the selected window and the designated projector is completed (step S160: Yes), the CPU 200 executes the image processing module M5 and executes image processing on display image data as necessary (step S170). In this embodiment, the image processing for the display image data is executed on each of the projector transfer storage areas PJS1 to PJS3. In the image processing, for example, resolution conversion processing, image quality adjustment processing such as sharpness, luminance adjustment, and color balance, and display image data composition processing using projector information are executed. When it is requested to project a plurality of windows to one projector by the composition processing, display image data according to the image displayed on the display 40 can be transferred to the projector 30.

  The CPU 200 executes the communication control module M6 and transfers the image data for display stored in the projector transfer storage areas SPJ1 to SPJ3 to which the image processing has been performed to the corresponding projectors PJ1 to PJ3 ( Step S180), this processing routine is terminated. Note that after the association between the window and the projector 30 is completed, generation of window display image data on the display 40 and transmission of the display image data to each projector 30 (PJ1 to PJ4) are performed at a predetermined timing. Will be executed repeatedly. Alternatively, when the content is content that does not involve time transition, generation of image data for display of the corresponding window and display image for each projector 30 (PJ1 to PJ4) at the timing when the window becomes active. Data transmission may be performed. Thus, an image corresponding to the latest window can always be projected even after the window and the projector 30 are associated with each other.

Layout operation:
FIG. 9 is a flowchart showing a processing routine executed for the layout operation. As shown in FIG. 5, the image transfer apparatus 20 according to the present embodiment has a layout for displaying the layout of the window transferred to the projector 30 on the primary screen of the display 40, that is, generally the desktop screen. A display area LA is provided. The layout display area LA is displayed / hidden by the user, for example, by a selection button arranged on the primary screen or on the title bar of each window. When display is selected by the user, the CPU 200 executes the display control module M9 and displays, for example, a rectangular frame line for partitioning the layout display area LA on the upper left side of the primary screen. The layout display area LA preferably has the same aspect ratio as the primary screen. The display control module M9 displays a layout display window indicating the layout of the window transferred to the projector 30 or transferred from now on in the layout display area LA. Here, the layout of the window means the layout on the projection surface of the image projected by the projector 30, for example, the position and size of the projected image with respect to the projection frame that can be projected by the projector 30.

  In the example of FIGS. 5 and 7, the display image data of the windows W2 and W3 among the windows displayed on the display 40 is transferred to the projector 30. Therefore, in the layout display area LA, Only layout display windows W2L and W3L corresponding to these windows W2 and W3 are displayed. The sizes of the layout display windows W2L and W3L are scaled at a predetermined ratio with respect to the sizes of the windows W2 and W3. The positions of the layout display windows W2L and W3L are the windows W2, W3 with respect to the projection frame. Corresponds to the projection position of the projection image using the display image data. Further, the layout display windows W2L and W3L may not be displayed up to the contents (contents) of the corresponding windows W2 and W3. For example, they may be displayed as frames or empty windows.

  For example, the display control module M9 uses the display image data stored in the window storage area to perform resolution conversion according to a predetermined scale ratio, and also provides coordinate information given to the display image data. Is used to calculate the display coordinate position on the primary screen corresponding to the display coordinate position in the layout display area LA. The display control module M9 draws a layout display window in the VRAM 230 using the frame data of the display image data subjected to resolution conversion and the calculated coordinate position information. In the layout display area LA, the layout display windows may be displayed overlapping each other.

  For the layout display window, for example, operations such as resizing and moving can be performed via the input device 41 such as a mouse and a keyboard, and these operations are also reflected in a projected image projected via the projector 30. The When CPU 200 detects an operation on the layout display window, it starts the layout display change process shown in FIG.

  If the CPU 200 determines that the operation on the layout display window is the movement process shown in FIG. 5 (step S200: movement), it acquires information about the movement (step S210) and displays image data for display in the projector transfer storage area. Is stored (step S220). FIG. 5 shows an example in which the layout display window W3L has been moved in the direction of the arrow from the original location indicated by the broken line. The information regarding the movement is, for example, the movement amount (movement distance) in the X and Y directions of the layout display window in the layout display area LA. The CPU 200 obtains the movement amount in the X and Y directions of the display image data on the storage area using the acquired information on the movement and the information on the resolution of the display image data, and obtains all of the display image data. The X and Y coordinates of the pixel data are changed.

  The CPU 200 transfers the corrected display image data to the projector 30 associated with the transfer storage area (step S230), and ends this processing routine. As a result, as shown in FIG. 6, the display position of the image PW3 projected by the projector 30 with respect to the projection frame PF of the projector 30 is changed. It should be noted that even if the layout display window in the layout display area LA is moved, the corresponding window on the display display 40 is preferably not moved. The movement of the display window in the layout display area LA is a process aimed at changing the projection position of the image projected by the projector 30 and has little relation to the display position of the corresponding window on the display display 40. This is because the movement of the corresponding window on the display 40 may hinder other processing such as processing of the contents for the window. For example, even when another window is moved by an operation in the layout display area LA in order to perform some processing on one window on the display 40 on which a plurality of windows are displayed, The projection position of the other window by the projector 30 is not changed, and unnecessary fluctuation of the projected window can be prevented or suppressed.

  If the operation for moving the layout display window out of the layout display area LA is executed by the moving operation, the layout display window may be displayed so as to protrude from the layout display area LA, or the layout calculation may be performed by executing coordinate calculation. You may display so that it may stop in the use area | region LA. In the former case, the image processing (storage position changing process) for the display image data for projector transfer in response to an operation that protrudes from the layout display area LA has a storage position so that the projection position does not protrude from the projection frame. The storage position may be changed so that the projection position protrudes from the projection frame. This is because in this embodiment, the display image data is generated for the entire window and can be used in any case. On the other hand, in the latter case, the image processing (storage position change processing) for the display image data for projector transfer in response to an operation that protrudes from the layout display area LA has a storage position so that the projection position does not protrude from the projection frame. Be changed. These processes for the moving operation may be processes that can be appropriately selected by the user.

  Hereinafter, a case where the operation on the layout display window is the resizing process will be described. FIG. 10 is an explanatory diagram showing another example of a screen on a display display on which a plurality of windows are displayed. FIG. 11 is an explanatory diagram showing an example of an image change on the projector corresponding to the window whose size has been changed in FIG. FIG. 12 is an explanatory diagram schematically showing a memory area of a RAM for storing display image data for each window shown in FIG. FIG. 13 is an explanatory diagram showing an example of a table storing the correspondence between projectors and windows.

  On the other hand, when the CPU 200 determines that the operation on the layout display window is the resizing process (step S200: resizing), the CPU 200 acquires information on resizing (step S240), and the resolution (projection) of the display image data in the display storage area. (Size) is changed (step S250). The information about resizing is, for example, the ratio of the vertical and horizontal size after the change to the vertical and horizontal size before the change of the layout display window in the layout display area LA. The CPU 200 converts the resolution of the display image data on the storage area using the acquired information about the resizing.

  The CPU 200 transfers the display image data from the display storage area to the transfer storage area associated with the display storage area, and transfers the corrected display image data to the projector 30 associated with the transfer storage area. (Step S230), and this processing routine is terminated. As a result, as shown in FIG. 11, the size of the image PW2 projected by the projector 30 is changed. In the example of FIG. 11, the layout display window W2L is projected by the two projectors 30 because the maximum size of the primary screen is exceeded as the size of the layout display window changes as described later. That is, a part of the image PW2 is projected onto the projection frame PF1 of the first projector, and the remaining part of the image PW2 is projected onto the projection frame PF2 of the second projector. Note that the size of the corresponding window on the display 40 may be changed in accordance with the size change of the layout display window in the layout display area LA. The resizing of the display window in the layout display area LA is a process whose first purpose is to change the size of the image projected by the projector 30, but in the process of changing the contents of the corresponding window on the display display 40. This is because changing the size of the projected image may show a high degree of relevance, and the processing for the window can be facilitated.

  In addition, since the resolution of the display image data in the display storage area is changed, the processing using the display image data stored in the same display storage area, for example, the active window on the display display 40 is changed. When the corresponding display image data is read, the resized display image data is used. As a result, as the size of the layout display window in the layout display area LA is changed, the size of the corresponding window on the display display 40 is easily changed.

  Here, generally, the maximum size of an image displayed on the display 40 is limited to the size of the primary screen. Therefore, normally, the maximum size of the layout display window in the layout display area LA cannot exceed the layout display area LA, and the zoom magnification provided by the projector 30 cannot be exceeded. However, in this embodiment, as described below, resizing exceeding the size (resolution) of the primary screen is allowed. The technique relating to the change of the window size is a technique well known to those skilled in the art and will be briefly described below.

  In the example shown in FIG. 10, the layout display window W2L in the layout display area LA is changed from the original size indicated by the broken line to a size that protrudes from the layout display area LA1 by the user's enlargement operation in the arrow direction. Yes. When the layout display window protrudes from the layout display area LA1 due to the resizing operation by the user, the CPU 200 (display control module M9) displays a new layout display area LA2 in the direction expanded by the resizing operation, and The entire layout display window after resizing is displayed by the layout display areas LA1 and LA2. When the size of the layout display window displayed by the plurality of layout display areas LA1 and LA2 is reduced, the number of layout display areas LA is appropriately within a range in which the entire layout display window can be displayed. Is reduced. As a result of the resizing operation on the layout display window W2L in the layout display area LA, the size of the window W2 is changed to a size exceeding the size of the primary screen by the user, and the whole of the window W2 does not fit on the display 40, and part of the window W2 It protrudes from the display screen of the display 40 and becomes invisible.

  The window size change on the primary screen is controlled by the operating system (OS). When the user requests a window size change for the application program (window), the OS uses an API message WM_GETMINMAXINFO as an application program. Send. WM_GETMINMAXINFO is a pointer that points to a MINMAXINFO structure. The MINMAXINFO structure stores information about the size and position of the window when it is maximized, and the tracking size when it is maximized and iconified. Normally, the application program that has received WM_GETMINMAXINFO returns the value set in the MINMAXINFO structure by default to the OS without changing the default value. On the other hand, in the present embodiment, the image processing module M5 obtains the resize value of the layout display window W2L whose size has been changed in the layout display area LA, and obtains the maximum tracking width (ptMaxTrackSize.x) and high of the window. Change (ptMaxTrackSize.y). As a result, since the OS allows the maximum value (x, y) set as the maximum value of the window size on the display 40, the display control module M9 sets a limit (default value) in the layout display area LA. You can resize windows beyond.

  Further, as described above, in the present embodiment, display image data representing the entire window is generated for a window at least a part of which is displayed on the display 40. As a result, the display image data of the window W2 resized so as to exceed the size of the primary screen is stored across the first and second storage areas A1 and A2, as shown in FIG. In the example of FIGS. 10 and 12, the first storage area A1 is for the first projector PJ1, the second storage area A2 is for the second projector PJ2, and the third storage area A3 is for the third projector PJ3. The fourth storage area A4 is associated with the fourth projector PJ4. Therefore, a part of the window W2 stored in the first storage area A1 is in the first projector PJ1, the remainder of the window W2 stored in the second storage area A2 is in the second projector PJ2, and The window W3 stored in the third storage area A3 is associated with the third projector PJ3.

  In this embodiment, each storage area is secured so that the vertical or horizontal sides are in full contact with the adjacent storage area, that is, continuous, and a display corresponding to one window is provided by a plurality of adjacent storage areas. One virtual storage area for storing the image data can be formed. Further, since the arrangement of the storage areas is ensured corresponding to the arrangement of the projectors PJ1 to PJ4, it is possible to project an image based on the developed image of the display image data on each storage area. That is, the display image data of the window W2 stored in the first storage area A1 is projected by the first projector PJ1, and the display image data of the window W2 stored in the second storage area A2 is the first. 2 is projected by the second projector PJ2. Therefore, an image of the entire window W2 that cannot be projected by one projector 30 can be projected onto the projection surface as one image PW2 by the two projectors PJ1 and PJ2, as shown in FIG. Since each storage area is managed by coordinate information, even if the storage area for storing a part of the window W2 and the storage area for storing the remaining part of the window W2 are not adjacent to each other, the storage areas are adjacent to each other. By transferring the display image data corresponding to a part of the window W2 and the display image data corresponding to the remaining part of the window W2, respectively, to the projector 30 arranged in this manner, the image of the entire window W2 is transferred. Can project.

  Note that since the image exceeding the primary screen cannot be displayed on the display 40, only the image based on the display image data stored in one of the first and second storage areas A1 and A2 is displayed. It is displayed on the display 40.

  As another window operation in the layout display area LA, an operation of changing the display order (overlapping order) of the layout display windows is possible. In this operation, for example, when a left click input (selection input) of the mouse is input on a desired layout display window, or the order is displayed in the display order list of the layout display window displayed in the layout display area LA. As a result, the display order of the layout display window is changed.

  The display order of the layout display windows in the layout display area LA may or may not be reflected in the display order of the windows displayed on the display 40. When reflected, the active window can be selected by the selection operation in the layout display area LA, and the selection of the active window on the display 40 can be simplified.

  As described above, according to the image transfer apparatus 20 according to the present embodiment, the layout displaying the layout display window corresponding to the layout at the time of projection of the display image data transferred to each projector 30 on the display display 40. Since the display area LA is provided, the layout of the image projected by each projector 30 can be easily grasped.

  According to the image transfer apparatus 20 according to the present embodiment, the layout of the image displayed by each projector 30 can be changed by an operation on the layout display window in the layout display area LA. For example, the size and display position (projection position with respect to the projection frame) of the image displayed by each projector 30 can be changed by an operation of resizing or moving the layout display window in the layout display area LA. Therefore, the layout of images projected by the plurality of projectors 30 can be managed and corrected via one screen. In particular, when a plurality of windows can be separately projected via a plurality of projectors 30 by a single image transfer device 20, the projection layout of the windows displayed on the display 40 is centrally managed. It is possible to improve the convenience.

  In this embodiment, when the size of the window on the display 40 is changed, display image data whose size has been changed is generated at the next capture timing, transferred to the projector 30, and displayed in layout. The display size of the layout display window in the area LA is changed. That is, the size of the image displayed on the layout display area LA and the size of the image projected by the projector 30 are changed by the size changing operation on the window displayed on the display 40. On the other hand, when only the position of the window on the display 40 is changed, the coordinate position of the display image data in the storage area may not be changed from the initial coordinate position (pasting position). In this case, the projection position of the image projected by the projector 30 and the display position of the layout display window in the layout display area LA are not changed.

  Further, in the image transfer apparatus 20 according to the present embodiment, resizing exceeding the size of the primary screen of the display 40 can be executed, so that the image transfer device 20 is arranged adjacent to each other without being limited by the size of the primary screen. The size of the projected image can be easily set to a desired size using a plurality of projectors.

  Furthermore, according to the image transfer apparatus 20 according to the present embodiment, an active window can be selected for a window displayed on the display display 40 in the layout display area LA. Therefore, it becomes possible to select an active window from only windows corresponding to images projected by the projector 30, and the selection of the active window can be facilitated.

  Further, according to the image transfer apparatus 20 according to the present embodiment, a plurality of windows are transferred to the plurality of projectors 30 without installing special driver software for the projector 30 in a personal computer or the like, and the projectors 30 are passed through the projector 30. Projects and can easily manage and modify the layout.

  According to the image transfer apparatus 20 according to the present embodiment, it is possible to execute image processing on display image data to be transferred to the projector 30 while holding captured display image data. In other words, the image transfer apparatus 20 according to the present embodiment includes two storage areas, ie, a display storage area and a projector transfer storage area. The display image data subjected to the image processing can be transferred to the projector 30 without changing the display image data.

  Furthermore, according to the image transfer apparatus 20 according to the present embodiment, the state of the primary display on the display display 40 can be easily projected. That is, in this embodiment, the display image data for each window is generated separately, so that the display image data including the entire window is obtained by the synthesis process. In this embodiment, by utilizing the projector transfer storage area, display image data corresponding to each window stored in the display storage area can be easily combined.

Other examples:
(1) In the above embodiment, the display storage area and the projector transfer storage area are described as being secured on the RAM 210. However, only the display storage area or the projector transfer storage area is used. May be. When only the display storage area is used, each display storage area and each projector 30 are associated with each other, so that a desired window can be projected onto each projector. In this case, the same number of display storage areas as the number of windows displayed on the display display 40 are secured on the RAM 210, and image processing including resizing and moving display image data is executed in the display storage area. Further, when the display image data of the same window is transferred to the plurality of projectors 30, the plurality of projectors 30 are associated with one display storage area. In associating each display storage area with each projector 30, for example, first, display image data of all windows displayed on the display 40 is generated, and each window is associated with each projector 30. Accordingly, the corresponding display image data may be stored in the display storage area. In this case, since the display image data of all windows displayed on the display 40 is generated in advance, even when the association between the window and the projector 30 is changed, the corresponding display data is immediately displayed. Image data can be transferred to the projector 30.

  When only the projector transfer storage area is used, each projector transfer storage area and each projector 30 are associated with each other, so that a desired window can be projected to each projector. In this case, as many projector transfer storage areas as the number of projectors 30 connected to the image transfer apparatus 20 are secured on the RAM 210, and image processing including resizing and moving display image data is executed in the projector transfer storage area. Is done. Further, even when display image data for the same window is transferred to a plurality of projectors 30, display image data for the same window is stored in each projector transfer storage area. In associating each projector transfer storage area with a window, for example, display image data corresponding to the selection of a window to be transferred to each projector 30 is generated and stored in the projector transfer storage area. Even when the number of windows displayed on the display 40 is different from the number of connected projectors, the projector transfer storage area can be used effectively.

  Furthermore, when only the projector transfer storage area is used, the capacity of the storage area for storing the display image data can be reduced. That is, since the display image data is sequentially generated for the selected windows, it is not necessary to generate the display image data corresponding to the windows that are not selected. Further, in this aspect, only the display image data for the window to be transferred to the projector 30 is generated, and the storage area is released after the transfer, so the capacity of the storage area can be reduced. Note that if the same window needs to be captured, generation of window display image data may be executed again.

(2) In the above embodiment, the window is selected by, for example, selecting a desired window (content) with the mouse (for example, left-clicking), or moving the mouse cursor over the desired window. May be executed by. In this case, the user can easily select a window.

(3) In the above embodiment, the generated display image data may be repeatedly updated at a predetermined timing. Consistency between the image projected through the projector 30 by the update and the window on the display 40 can be achieved. Further, display image data may be generated (captured) at the timing when the window becomes active. In this case, unnecessary update of the display image data can be suppressed. In addition, the update timing may be a window, that is, if the content is related to a moving image, it may be shorter than the case of other content, and only the difference data is used to reduce the amount of transferred data. May be transferred.

(4) In the above embodiment, image processing is performed in the projector transfer storage area in the case of the layout display window moving operation in the layout display area LA, and in the display storage area in the case of the layout display window resizing operation. Although being executed, image processing may be executed in the display storage area and the projector transfer storage area, respectively.

(5) In each of the above embodiments, when the capacity of the display image data storage area or projector transfer storage area for the window or projector 30 is insufficient, the storage area capacity corresponding to a resolution lower than the resolution of the primary display May be secured, or a storage area capacity corresponding to the resolution of the primary display may be secured until the capacity becomes insufficient. In the former case, display image data after resolution conversion may be stored, and in the latter case, display image data stored in each storage area may be sequentially switched.

(6) In each of the above-described embodiments, the projector has been described as an example of the image projection device 30. However, for example, a projection display monitor may be used. Furthermore, a normal display may be used in place of the image projection apparatus. Also in this case, a different window can be displayed for each display.

(7) In the above embodiments, the image transfer process is realized by software, but may be realized by hardware. In this case, for example, it can be realized as a board provided with a logic circuit for executing image transfer processing, or a board provided with a logic circuit and a storage device.

  As mentioned above, although this invention was demonstrated based on the Example and the modification, Embodiment mentioned above is for making an understanding of this invention easy, and does not limit this invention. The present invention can be changed and improved without departing from the spirit and scope of the claims, and equivalents thereof are included in the present invention.

DESCRIPTION OF SYMBOLS 10 ... Image transfer system 20 ... Image transfer apparatus 200 ... CPU
210 ... RAM
220 ... HDD
230 ... VRAM
240 ... Input / output interface 250 ... Bus 30 ... Image projection device 300 ... CPU
310 ... RAM
320 ... ROM
330 ... VRAM
340 ... Image display unit 350 ... Optical system 360 ... Input / output interface 370 ... Bus 40 ... Display display 41 ... Input device P1 ... Image transfer program M1 ... Window selection module M2 ... Projector designation module M3 ... Storage control module M4 ... Display image Data generation module M5 ... Image processing module M6 ... Communication control module M7 ... Projector information acquisition module M8 ... Connected projector management module M9 ... Display control module M31 ... Projector information transmission module M32 ... Drawing module I33 ... Projector information CV ... Cable

Claims (14)

An image transfer device to which a plurality of image projection devices can be connected,
A display capable of displaying multiple contents;
A display image data generation unit that generates display image data of each content at least a part of which is displayed on the display;
A storage device for storing the display image data in a storage position associated with an image projection position by the image projection device;
A storage control unit for storing each of the connected image projection devices and the generated display image data in association with each other in the storage device;
A transfer unit that transfers the associated display image data to the image projection devices;
An image is displayed on the display using the display image data, and a plurality of layout display images corresponding to the display image data transferred to the image projection apparatuses are displayed on the display. An image transfer apparatus comprising: a display control unit that displays in a layout display area. The image transfer apparatus according to claim 1 further includes:
When an operation is performed on the layout display image, image processing that reflects the performed operation is executed on the display image data corresponding to the layout display image on which the operation has been performed. An image transfer apparatus including an image processing unit. The image transfer apparatus according to claim 2,
The operation is an operation of changing the size of the layout display image, and the image processing unit converts the resolution of the display image data in accordance with the change of the size,
The transfer unit transfers the image data for display subjected to the image processing to the corresponding image projection apparatus. The image transfer apparatus according to claim 3.
The display control unit is an image transfer device that displays an image whose size has been changed on the display using the display image data subjected to the image processing. The image transfer apparatus according to claim 2,
The operation is an operation of changing a display position of the layout display image, and the image processing unit changes the storage position of the display image data in the storage device according to the change of the display position,
The transfer unit transfers the image data for display subjected to the image processing to the corresponding image projection apparatus. The image transfer apparatus according to any one of claims 1 to 5, further comprising:
A selection unit for selecting one content from a plurality of contents displayed on the display;
A designation unit for designating an image projection apparatus that projects the selected content;
The storage control unit stores the selected display image data and the specified image projection device in the storage device in association with each other. The image transfer apparatus according to any one of claims 2 to 6,
The storage control unit secures a content storage area for storing the display image data in the storage device according to the number of contents displayed on the display, and the display image data An image transfer apparatus stored in a storage position associated with an image projection position by the image projection apparatus in the content storage area. The image transfer apparatus according to claim 7, wherein
The image processing unit is an image transfer device that performs image processing on the image data in the content storage area. The image transfer apparatus according to any one of claims 2 to 7,
The storage control unit secures a storage area for transfer for storing the display image data for transfer to the image projection apparatus in the storage apparatus according to the number of the connected image projection apparatuses, The display image data is stored in a storage position associated with a projection position of an image by the image projection apparatus in each transfer storage area. The image transfer apparatus according to claim 9, wherein
The image processing unit is an image transfer device that performs image processing on the image data in the transfer storage area. The image transfer apparatus according to claim 7, wherein
The content storage area is secured corresponding to the arrangement of the connected image projection devices,
The storage control unit stores the display image data in a plurality of content storage areas corresponding to the adjacent image projection devices when the capacity of the display image data exceeds the capacity of the content storage area. ,
The display control unit is an image transfer device that displays a layout display image corresponding to the display image data in a plurality of adjacent layout display areas. The image transfer apparatus according to claim 1,
The layout display area is an image transfer apparatus having the same aspect ratio as the display screen of the display. The image transfer apparatus according to claim 1,
The image transfer apparatus, wherein the display control unit changes an overlapping order of the plurality of layout display images in the layout display area in accordance with an operation for changing the overlapping order of the plurality of layout display images. An image display control method in image transfer,
Generate display image data for each content that is at least partially displayed on the display,
Each connected image projection device and each of the generated display image data are stored in a storage device in association with each other,
Transfer each display image data associated with each image projection device,
An image display control method for displaying a plurality of layout display images corresponding to each display image data transferred to each image projection apparatus in a layout display area on the display.

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