JP2012220595A - Display device, control method of display device, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device, a control method of the display device, and a program capable of easily selecting and displaying any one of images input from a plurality of image provision devices.SOLUTION: A projector 11 includes projection units 3 for displaying input image data that is input from PCs 13, a display control unit 107 for dividing a display region on a screen SC into a plurality of regions and switching between a division display state in which the multiple pieces of input image data that is input from each of the plurality of PCs 13 is displayed in each of the divided regions and an entire region display state in which any one of the input image data is displayed in an entire display region, and an image detection unit 125 for detecting that any of the input image data is in a predetermined state. When it is determined that any of the input image data is in a predetermined state by the image detection unit 125, the display control unit 107 instructs the projection units 3 to display the detected input image data in the entire region display state.

Description

  The present invention relates to a display device that displays an image, a control method for the display device, and a program.

  Conventionally, a display that can be switched between a mode in which a display area is divided into a plurality of different images (so-called split display) and a normal mode in which a single image is displayed in the entire display area (so-called full screen display). An apparatus is known (see, for example, Patent Document 1). This type of display device is connected to a plurality of image supply devices such as a personal computer, and is divided into images that are input from each image supply device, and a full screen that displays images input from any of the image supply devices. The display can be switched.

JP 2006-330468 A

By the way, when switching from split display to full screen display, it is necessary to operate the image supply device or the display device to select any one of the split-displayed images. There was a problem that it took time and effort.
The present invention provides a display device, a display device control method, and a program that can solve the above-described problems of the conventional technology and can easily select and display any of images input from a plurality of image supply devices. The purpose is to do.

In order to achieve the above object, the present invention provides a display device for displaying an input image input from an image supply device, the display means for displaying the input image, and a plurality of display areas of the display means. A divided display state in which the plurality of input images input from each of the plurality of image supply devices are displayed in each divided area, and any one of the input images is displayed in the entire display area. Display control means for switching between all-region display states, and image detection means for detecting that any one of the input images is in a predetermined state, wherein the display control means is selected by any one of the image detection means. When it is detected that the input image is in a predetermined state, the detected input image is displayed in the whole area display state by the display means.
According to the present invention, when any one of the input images input from the plurality of image supply devices is in a predetermined state, the input image is displayed in the entire display area. The display state can be easily switched and a desired input image can be displayed on the entire display area without performing an operation for instructing switching or an operation for designating an input image to be displayed on the entire display area.

In the display device according to the present invention, the image detection unit may be configured such that the input image is a frame image in which a window frame is provided in the image and an object is displayed in the window frame, or a window in the image. It is determined whether the object is a full-screen image displayed on the entire image without a frame, and when the object is a full-screen image, it is detected that the input image is in the predetermined state. .
According to the present invention, if the input image input from the image supply device is a full-screen image without a window frame, the input image is displayed over the entire display area, so the state of the image output by the image supply device It is possible to display the desired input image in the entire display area by switching the display state of the display device simply by controlling the display.

In the display device, the image detection unit detects that the input image detected to be in the predetermined state is no longer in the predetermined state, and the display control unit When the input image being displayed in the entire area display state is detected by the image detecting means to be no longer in the predetermined state, the input image is switched from the entire area display state to the divided display state.
According to the present invention, when the input image displayed in the entire display area is not in a predetermined state, the display is switched to the split display state, so that it is easy without performing an operation to instruct the switch to the split display state. It is possible to return to the split display state.

In the display device according to the aspect of the invention, the display control unit may display one of the input images from the other image supply device by the image detection unit while the display unit displays the input image in the entire area display state. When it is detected that the input image to be input is in the predetermined state, the input image newly detected to be in the predetermined state is displayed in the entire area display state. And
According to the present invention, when an input image is displayed in the entire display area and another input image is in a predetermined state, the input image in the predetermined state is displayed on the entire display area later. Therefore, it is possible to switch the image to be displayed in the entire display area by simply controlling the state of the image output from the image supply device without performing an operation for instructing switching of the input image.

According to the present invention, the display device includes a digital interface through which the input image is input from the image supply device, and digital image data is input through the digital interface.
According to the present invention, since an input image input from the image supply device is input as digital image data, it can be displayed without degrading image quality, and the input image is in a predetermined state by digital processing. Can be easily detected.

In order to achieve the above object, the present invention provides a control method for a display device including display means for displaying an input image input from an image supply device, wherein the display means displays a plurality of display areas. A divided display state in which the plurality of input images input from each of the plurality of image supply devices are displayed in each of the divided regions, and any one of the input images is displayed over the entire display region. When switching between the whole area display state to be displayed and detecting that any one of the input images is in a predetermined state, the detected input image is displayed in the whole area display state by the display means. Features.
By executing the display method of the present invention, when any of the input images input from the plurality of image supply devices to the display device is in a predetermined state, the input image is displayed over the entire display area. Therefore, it is possible to easily switch the display state without performing an operation for instructing switching from the split display state or an operation for designating an input image to be displayed on the entire display area, and a desired input image is displayed on the entire display area. Can be displayed.

In order to achieve the above object, the present invention is a program executable by a computer that controls a display device including a display unit that displays an input image input from an image supply device, the computer comprising: An image detection unit that detects that any one of the input images is in a predetermined state, and a display area displayed by the display unit is divided into a plurality of regions, and each of the divided regions includes a plurality of the image supply devices. Switching between a split display state in which a plurality of the input images input from each of them are displayed and an entire region display state in which any one of the input images is displayed in the entire display region, When it is detected that the input image is in a predetermined state, the display control means for displaying the detected input image in the entire area display state by the display means. Is a program to function as.
By executing the program of the present invention with a computer, when any of the input images input from the plurality of image supply devices to the display device is in a predetermined state, the input image is displayed over the entire display area. Therefore, it is possible to easily switch the display state without performing an operation for instructing switching from the split display state or an operation for designating an input image to be displayed on the entire display area, and a desired input image is displayed on the entire display area. Can be displayed.

  According to the present invention, it is possible to easily switch a display state and display a desired input image on the entire display area without performing an operation for instructing switching of a display state, an operation for specifying an input image, or the like.

It is a block diagram which shows the structure of the projector which concerns on embodiment to which this invention is applied. It is a figure which shows the example of the image projected on the screen SC by a projector, (A) shows the example of a division | segmentation display state, (B) shows the example of a whole area display state. It is a figure which shows the example of the input image input into a projector from PC, (A) is an example of a frame image, (B) is an example of a full screen image. It is a flowchart which shows operation | movement of a projector. It is a flowchart which shows operation | movement of a projector. It is a flowchart which shows another example of operation | movement of a projector.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a functional configuration of a display system 10 including a projector 11 as a display device to which the present invention is applied. The projector 11 is connected to a plurality of PCs (personal computers) 13 as image supply apparatuses via a communication network 17, and an input image input from the plurality of PCs 13 via an interface (I / F) 101 is displayed on a screen SC. It is a device that projects. Examples of the image supply device that supplies an input image to the projector 11 include a video playback device, a DVD playback device, a TV tuner device, a CATV set top box, a video output device such as a video game device, a personal computer, and the like. In the embodiment, a case where digital image data is input from the PC 13 will be described as an example.
The communication network 17 is a network capable of bidirectional communication such as a LAN (Local Area Network) configured by a wired or wireless communication line, and connects each PC 13 and the projector 11 so that they can communicate with each other. Mutual communication is also possible.

  Since a plurality of PCs 13 constituting the display system 10 all have the same configuration, the functional configuration of one PC 13 is illustrated here. As shown in FIG. 1, the PC 13 executes a predetermined program to control each unit of the PC 13, a ROM 132 that stores a basic control program executed by the CPU 131, data related to the basic control program, and the like in a nonvolatile manner. A RAM 133 that temporarily stores programs and data executed by the CPU, a storage unit 134 that stores application programs executed by the CPU 131, an input unit 135 that detects an input operation by an input device (not shown) such as a keyboard and a mouse, and The display unit 136 displays various screens on the monitor 14 (display screen) according to the control of the CPU 131, and these units are connected to each other via a bus.

  The PC 13 starts to operate according to the operation detected by the input unit 135, and executes the application program designated by this operation by the CPU 131, and creates various data such as a presentation file including a plurality of images for presentation, for example. . Further, the PC 13 executes a projector control program for controlling the projector 11 by the CPU 131. When the projector control program is executed, the PC 13 displays an image on the monitor 14 by the function of the display unit 136 and also supplies image data for displaying the same screen as the screen displayed on the monitor 14 to the projector 11. Send.

The I / F 101 provided in the projector 11 is a digital interface, and includes an interface having connectors and input / output circuits compliant with the DVI standard, HDMI standard, etc., or a LAN interface through which image data and control data are input / output. Can be mentioned.
The image data of the input image input from the PC 13 to the I / F 101 includes information on the image format of the image data (including the 3D video format, frame rate, and the like) along with the image data itself.

The projector 11 can display either a still image or a moving image (video). In the following description, a case of displaying and outputting a still image input from the PC 13 will be described as an example. However, in the following description, the process of displaying an input image can be applied as it is to display a moving image. is there.
In this embodiment, the screen SC is almost upright, and the screen surface is rectangular. The image input to the projector 11 may be either a moving image (video) or a still image. The projector 11 can project a video on the screen SC or can continue to project a still image on the screen SC.

The projector 11 has a split display state in which input images input from a plurality of PCs 13 are displayed by dividing a display area on the screen SC, and an input image input from one PC 13 is displayed on the entire display area on the screen SC. It is possible to switch between the entire area display states displayed on the screen. The display area refers to an area that the entire image projected by the projector 11 occupies on the projection surface such as the screen SC. For example, when a wall surface or the like is used as a screen, a range in which the projection light of the projector 11 falls is a display area. In the screen SC and the wall surface, a portion where the projection light of the projector 11 does not strike is not included in the display area.
FIG. 2 is a diagram illustrating an example of an image projected by the projector 11 on the screen SC. FIG. 2A illustrates an example of a divided display state, and FIG. 2B illustrates an example of an entire region display state.
In the state shown in FIG. 2A, the projection image 200 is formed by the projection light of the projector 11 on the screen SC. The projected image 200 is divided into a plurality of areas 201, and input images from different PCs 13 are displayed in the respective areas 201. Although the number of divisions of the projected image 200 is arbitrary, in the present embodiment, an example in which the projection image 200 is divided into four regions 201 will be described. Further, each area 201 on the screen SC may be configured to be divided into screens of substantially the same size according to the number of divisions, or the user operates the operation panel 45 or a remote controller (not shown), The configuration may be such that any one area 201 can be enlarged and the remaining area 201 can be reduced accordingly. In the example of FIG. 2A, four PCs 13 are connected to the projector 11, and the display area is divided into four by the screen division processing unit 126, so that four areas 201 of the same size are arranged.
In the entire area display state, the projector 11 displays one input image in the display area on the screen SC. That is, as illustrated in FIG. 2B, in the projected image 210 of the screen SC, an input image from one PC 13 is displayed in the entire display area on the screen SC. Further, since the peripheral edge of the input image is usually black, the projected image 210 on the screen SC also has a black edge.

As shown in FIG. 1, a projector 11 is roughly divided into a projection unit 3 (display unit) that forms an optical image, and an image processing system that electrically processes a video signal input to the projection unit 3. It consists of. The projection unit 3 includes an illumination optical system 31, a liquid crystal panel 32 as a light modulation device, and a projection optical system 33. The illumination optical system 31 includes a light source including a xenon lamp, an ultra high pressure mercury lamp, an LED (Light Emitting Diode), and the like. The illumination optical system 31 may include a reflector and an auxiliary reflector that guide light emitted from the light source to the liquid crystal panel 32, and a lens group (not shown), a polarizing plate, A light control element or the like that reduces the amount of light emitted from the light source on the path to the liquid crystal panel 32 may be provided.
The liquid crystal panel 32 receives a signal from an image processing system, which will be described later, and forms an image on the panel surface. The liquid crystal panel 32 includes three liquid crystal panels corresponding to the three primary colors of RGB in order to perform color projection. Therefore, the light from the illumination optical system 31 is separated into three color lights of RGB, and each color light enters each corresponding liquid crystal panel. The color light modulated by passing through each liquid crystal panel is combined by a combining optical system such as a cross dichroic prism and emitted to the projection optical system 33.

The projection optical system 33 includes a zoom lens that performs enlargement / reduction of a projected image and a focus adjustment, a zoom adjustment motor that adjusts the degree of zoom, a focus adjustment motor that performs focus adjustment, and the like. The projection optical system 33 projects the incident light modulated by the liquid crystal panel 32 on the screen SC using a zoom lens.
The projection unit 3 includes a projection optical system drive unit 121 that drives each motor included in the projection optical system 33 according to the control of the control unit 103, and a light source drive that drives a light source included in the illumination optical system 31 according to the control of the control unit 103. The unit 117 is connected.

  The image processing system is configured around a control unit 103 that controls the entire projector 11 in an integrated manner, a storage unit 105 that stores data processed by the control unit 103 and a control program 105A executed by the control unit 103, and an operation panel 45. And an input processing unit 123 that detects an operation via the remote control light receiving unit 41, a display control unit 107 (display control unit) that processes an input video, and a buffer unit 110 that temporarily stores an input image input from the I / F 101. And a light modulator driving unit 119 that performs drawing by driving the liquid crystal panel 32 based on the video signal output from the display control unit 107.

  The control unit 103 reads out and executes the control program 105 </ b> A stored in the storage unit 105, thereby controlling each unit of the projector 11. The control unit 103 detects the content of the operation performed by the user based on the operation signal input from the input processing unit 123, and according to this operation, the display control unit 107, the light modulation device driving unit 119, the projection optical system. The driving unit 121 and the light source driving unit 117 are controlled to project an image on the screen SC.

In the main body of the projector 11, an operation panel 45 provided with various switches and indicator lamps for operation by the user is arranged. The operation panel 45 is connected to the input processing unit 123, and the input processing unit 123 turns on or blinks the indicator lamp of the operation panel 45 as appropriate according to the operation state and setting state of the projector 11 according to the control of the control unit 103. . When the switch of the operation panel 45 is operated, an operation signal corresponding to the operated switch is output from the input processing unit 123 to the control unit 103.
The projector 11 has a remote controller (not shown) used by the user. The remote control includes various buttons, and transmits an infrared signal corresponding to the operation of these buttons. The main body of the projector 11 is provided with a remote control light receiving unit 41 that receives an infrared signal emitted from the remote control. The remote control light receiving unit 41 decodes the infrared signal received from the remote control, generates an operation signal indicating the operation content on the remote control, and outputs the operation signal to the control unit 103.

  A buffer unit 110 that temporarily stores image data input from the PC 13 is connected to the I / F 101. The buffer unit 110 is provided with a plurality of image buffers 110 </ b> A that are independent storage areas in order to store image data input from a plurality of PCs 13 for each PC 13. The image buffer 110A may be obtained by virtually dividing one storage area. The number of image buffers 110A is arbitrary, but if there are as many image buffers 110A as the number of divisions for dividing the projection image 200 (FIG. 2A), that is, the number of regions 201, images are displayed in all regions 201. This is preferable because it is possible.

The display control unit 107 generates a display signal based on the image data stored in the image buffer 110 </ b> A of the buffer unit 110 under the control of the control unit 103, and outputs the display signal to the light modulation device driving unit 119.
Here, the display control unit 107 displays the image data stored in each image buffer 110A side by side in each divided area as shown in FIG. A screen division processing unit 126 that switches between the entire area display state in which the image data stored in the image buffer 110A is displayed in the entire display area is provided. In the divided display state, the screen division processing unit 126 selects the number of image buffers 110A corresponding to the number of divisions of the display area, and allocates and arranges the images of the selected image buffer 110A to the divided areas. In the entire area display state, the screen division processing unit 126 selects any one of the image buffers 110A and arranges the image of the selected image buffer 110A over the entire display area.

  The area to which the image data stored in each image buffer 110A is assigned may be determined based on a predetermined condition in advance, or the user may operate the operation panel 45 or the remote controller. An operation by an apparatus (not shown) may be performed and assigned to a desired area. Alternatively, the screen may be assigned to an arbitrary area by the screen division processing unit 126. For example, the network address on the communication network 17 assigned to the PC 13 or, if the PC 13 is connected to the I / F 101 by a cable (not shown), each cable is associated with the connected connector and divided. It may be determined in advance which area of the display area to allocate. Further, according to the order in which the PC 13 is connected to the projector 11, it may be determined which area of the divided display area is allocated.

  The display control unit 107 includes an image generation unit 127 that arranges the image data in the image buffer 110A according to the selection of the screen division processing unit 126 and generates one display image data. The image generation unit 127 adjusts the display state of the image, such as brightness, contrast, color density, hue, and projected image shape, with respect to the digital image data read from the buffer unit 110, and displays the display image for each frame. And the generated display image is developed in the frame memory 115. The display control unit 107 reads a display image from the frame memory 115 and outputs the read display image to the light modulation device driving unit 119. The light modulator driving unit 119 drives the liquid crystal panel 32 based on the display image input from the display control unit 107. As a result, the display image processed by the display control unit 107 based on the digital image data input from the PC 13 is drawn on the liquid crystal panel 32, and this image is projected onto the screen SC via the projection optical system 33. Projected as an image.

  Under the control of the control unit 103, the display control unit 107 arranges digital image data input from a plurality of PCs 13 and displays them divided in a display area, or displays data input from any one PC 13 over the entire display area. Controls what is displayed on the screen. Whether to perform division display or display in the entire area display state is determined based on screen division control information received from each PC 13. In the present embodiment, the screen division control information is set to an initial value so that the image is divided and displayed when the user does not particularly instruct.

  That is, the input image data input from the PC 13 to the projector 11 includes screen division control information that specifies how the input image from each PC 13 is displayed on the screen SC, that is, the display form on the screen SC. Yes. This screen division control information is generated when the PC 13 executes a projector control program by the CPU 131. While the projector control program is being executed, whether the input image data transmitted by the own apparatus is displayed in the above-described divided display state or the entire region display state by an operation detected by the input unit 135 of the PC 13. Can be specified. The contents designated here are added to the image data as screen division control information and transmitted to the projector 11.

  The display control unit 107 detects the screen division control information generated by each PC 13 from the input image data of the image buffer 110A by the screen division processing unit 126, and the screen division control information input from any of the PCs 13 is displayed in the entire area. When the state is designated, the input image from the PC 13 is displayed in the entire area display state. Further, when the screen division control information input from all the PCs 13 designates the split display state, the number of image buffers 110A corresponding to the preset number of screen divisions is selected, and as described above. Are displayed in a split display state by the projection unit 3.

  In addition to the control based on the screen division control information input from the PC 13, the screen division processing unit 126 automatically outputs the input image from the PC 13 when the input image from the PC 13 is in a predetermined state. It has a function to display in the whole area display state. Specifically, the image detection unit 125 (image detection unit) acquires each input image data of the image buffer 110A, and any one of the input image data is a full screen image in which the image is displayed on the entire screen. When detected, the input image data is displayed by the projection unit 3 in the entire area display state.

3 is a diagram illustrating an example of an image transmitted from the PC 13 to the projector 11. FIG. 3A is an example of a frame image, and FIG. 3B is an example of a full screen image.
The PC 13 normally displays on the monitor 14 a screen in which an operation image of the application program being executed is superimposed on a background screen generated as a function of basic software (operating system: OS) executed by the CPU 131. In this case, the image data transmitted from the PC 13 to the projector 11 by the function of the projector control program is the entire screen displayed on the monitor 14, for example, a frame image 220 shown in FIG.
In the frame image 220, a toolbar 221 displayed as an OS function is arranged at the bottom. The toolbar 221 can be arranged not only at the lower end of the screen of the monitor 14 but also at the end such as the left end, the right end, and the upper end. In the area excluding the toolbar 221, a window frame 222 as an operation screen of the application program is arranged. The window frame 222 displays an image, an operation menu bar, an icon, or the like by an application program such as presentation software within a frame of a predetermined design. The design of the outer frame 223 of the window frame 222 is determined by the specifications of the OS and the specifications of the application program. In the frame of the outer frame 223, an image being processed by the application program is displayed as an object.

  Here, when full screen display is instructed on the PC 13 by the function of the OS, the CPU 131 of the PC 13 displays the image being displayed in the window frame 222 on the entire screen which is the display area of the monitor 14. At this time, the input image data input from the PC 13 to the projector 11 is a full-screen image 230 obtained by enlarging the image displayed in the window frame 222 as illustrated in FIG. In the full screen image 230, the toolbar 221 and the outer frame 223 displayed by the OS of the PC 13 are not displayed, and the object displayed in the outer frame 223 in FIG. , Its periphery is outlined in black.

The image detection unit 125 of the projector 11 determines whether the input image data from the PC 13 is a frame image or a full screen image, and detects input image data that is a full screen image. In the storage unit 105, main application software such as presentation software and information indicating design features of the toolbar 221 and the outer frame 223 are stored in advance corresponding to the main OS. That is, features such as the size (number of pixels), color, and shape of the toolbar 221 and the outer frame 223 are stored for one or a plurality of OSs and application programs. The image detection unit 125 detects the toolbar 221 or the outer frame 223 from each input image data of the image buffer 110A based on the information stored in the storage unit 105, and when neither the toolbar 221 nor the outer frame 223 is detected. The input image data is determined as a full screen image and detected as input image data in a predetermined state. The screen division processing unit 126 displays the detected input image data in the entire area display state.
When the image detection unit 125 does not detect data in a predetermined state, the screen division processing unit 126 sets a plurality of display areas based on the screen division control information received from each PC 13. The image is divided into screens and displayed in the above-described divided display state.

Next, the operation of the projector 11 will be described.
FIG. 4 is a flowchart showing the operation of the projector 11.
The projector 11 receives an image and image division control information from a plurality of external PCs 13 (step S1). The projector 11 acquires an image transmitted from each PC 13 via the I / F 101, and stores the acquired image in each image buffer 110A of the buffer unit 110 for each PC 13 (step S2). Here, the projector 11 acquires the current display state (step S3). That is, it is acquired whether the image being projected on the screen SC is in a divided display state or an entire region display state.
Subsequently, the projector 11 detects input image data that is a full-screen image from the input image data of each image buffer 110A by the image detection unit 125 of the display control unit 107 (step S4). Then, it is determined whether any PC 13 is in full screen display and there is input image data that is a full screen image (step S5). If there is a PC 13 in full screen display (step S5: Yes), it is determined whether or not the display state acquired in step S3 is the entire region display state (step S6).

When the display state is the entire region display state (step S6: Yes), the projector 11 maintains the entire region display state and displays the input image data detected in step S4 in the entire region display state. The currently displayed image is updated (step S7). That is, when the projector 11 detects that the input image data of another PC 13 has become a full-screen image (predetermined state) while there is an image being displayed in the entire area display state, the projector 11 displays the image. The input image data is switched to the newly detected input image data and displayed in the entire area display state.
On the other hand, when the display state of the current display area is the split display state (step S6: No), the projector 11 switches the display state to the entire area display state and displays the input image data detected in step S4 ( Step S8).

  In addition, when the image detection unit 125 determines that there is no input image data that is a full-screen image (step S5: No), the projector 11 determines whether or not the display state acquired in step S3 is an all-region display state. Is determined (step S9). When the entire area display state is set (step S9: Yes), the projector 11 cancels the entire area display state (step S10), and shifts to the divided display state according to the setting by the function of the screen division processing unit 126. The image input from is displayed in each divided area (step S11). If the current display state is the split display state (step S9: No), the projector 11 continues the split display state (step S11). The projector 11 determines whether or not the projection has ended (step S12), and ends the operation when the projection has ended.

FIG. 5 is a flowchart showing the operation of the projector 11, and specifically shows the operation of detecting input image data that is a full-screen image by the image detection unit 125.
The process illustrated in FIG. 5 is a process in which the image detection unit 125 detects whether each image input from the plurality of PCs 13 is being displayed on the full screen on the supply source PC 13. The image detection unit 125 repeats this defined processing until the processing for all input image data stored in the buffer unit 110 is completed.
The image detection unit 125 reads out the image stored in each image buffer 110A of the buffer unit 110 (step S21), and determines whether or not there is a toolbar in the image. The tool bar is a strip-like GUI (Graphical User Interface) arranged along the upper and lower sides or the left and right sides (edges) of the screen as in the tool bar 221 shown in FIG. In general, the size (width) of the toolbar is determined by the specification of the OS being used and the setting of the screen resolution, and information indicating the characteristics of the toolbar for each OS is stored in the storage unit 105 as described above. . The color of the toolbar is usually a color other than black. On the other hand, when the input image is a full-screen image, as shown in FIG. 3B, the image is generally displayed in a black frame. The image detection unit 125 determines the presence or absence of an image toolbar based on these conditions.

  The image detection unit 125 acquires an image from the image buffer 110A, detects a line having a predetermined length or more other than black at the top, bottom, left, and right ends of the screen of the acquired image (step S22), and there is a corresponding line. It is determined whether or not (step S23). The detected line is a line having the same color as the arrangement of pixels of the same color connected in a straight line or the color of the toolbar stored in advance. When there is a line having a predetermined length or more other than black at any of the top, bottom, left, and right edges of the screen (step S23: Yes), the image detection unit 125 identifies the color of the line detected in step S22 (step S24). ). Subsequently, the image detection unit 125 moves the target line detected in step S22 in accordance with the size (width) of the OS toolbar used by the PC 13, and sets a line of the same color or longer than the target line as the target line. It is detected (step S25), and it is determined whether or not there is a corresponding line (step S26). When the OS used by the PC 13 is unknown, the image detection unit 125 repeatedly executes the processes of steps S25 to S26 using the features of the toolbars of all the OSs that store the features in the storage unit 105. If there is a line corresponding to any one of the features of the OS, it is determined as Yes in step S26.

If both Step S23 and Step S26 are Yes, a toolbar with a length longer than a predetermined length other than black and a width corresponding to the setting of the OS being used and the screen resolution is set at either the top, bottom, left, or right of the screen. It is determined that there is. In this case, the image detection unit 125 determines that the PC 13 that is the supply source of the image stored in the image buffer 110A is not in full screen display (step S27). Thereafter, the image detection unit 125 determines whether the processing for all the PCs 13 has been completed (step S29). For example, the image detection unit 125 sets a flag for the PC 13 for which the toolbar detection processing has been completed, and when the flag detection has been set for all the image detection units 125, the toolbar detection processing for all the PCs 13 has been completed. The structure which determines may be sufficient.
If the toolbar detection process for input image data from all PCs 13 has not been completed (step S29: No), the image detection unit 125 returns to step S21, and the input image for which the toolbar detection process has not been completed yet. Data is acquired from the image buffer 110A, and the above processing is executed. If it is determined that the toolbar detection process for all the PCs 13 has been completed (step S29: Yes), the image detection unit 125 ends the predefined process in FIG.

In addition, when the image detection unit 125 determines that the input image data acquired from the image buffer 110A has no line of a predetermined length or more other than black (step S23: No), the PC 13 that has transmitted the input image data It is determined that the full screen is being displayed (step S28).
Even when it is determined that there is a line having a length longer than a predetermined length other than black at the top, bottom, left, and right edges of the screen of the acquired image (step S23: Yes), the step is performed in accordance with the size (width) of the toolbar. When the target line detected in S22 is moved and it is determined that there is no line of the same color or longer than the predetermined length (step S26: No), the image detection unit 125 transmits the input image data. It is determined that the PC 13 that has been displayed is in full screen display.

  Next, another example of defined processing for detecting the PC 13 that is being displayed by the projector 11 and is displayed on the full screen will be described. The predefined process in FIG. 5 is a process for determining whether or not the input image data is a full-screen image based on the presence / absence of a toolbar in the input image data, but the input image data is based on the presence / absence of a window frame of application software. It is also possible to determine whether is a full-screen image or a frame image. The operation in this case will be described with reference to FIG.

FIG. 6 is a flowchart showing the operation of the projector 11, and specifically shows the operation of detecting input image data that is a full-screen image by the image detection unit 125.
The processing in FIG. 6 is executed in place of the processing in FIG. 5, and the image detection unit 125 performs the same processing as in FIG. 5 until the processing for all input image data stored in the buffer unit 110 is completed. repeat.

  First, the image detection unit 125 acquires an image stored in the image buffer 110A from the buffer unit 110 (step S30). Next, the image detection unit 125 acquires the window frame shape feature patterns of the main application software stored in advance in the storage unit 105 (step S31), and uses these window frame shape feature patterns to generate an image buffer. A window frame is detected in the input image data acquired from 110A (step S32), and it is determined whether there is a window frame (step S33).

If it is determined that there is a window frame (step S33: Yes), the image detection unit 125 is displaying the image stored in the image buffer 110A, and the input image data is a frame image. (Step S34).
On the other hand, if it is determined that there is no window frame (step S33: No), the image detection unit 125 acquires the detection result of the previous window frame of the image stored in the storage unit 105 for this input image data (step S35). ). Here, it is assumed that the previous window frame detection result and the previous full-screen image / frame image determination result are stored in the storage unit 105. Further, it can be determined based on the address of the PC 13 that transmitted the input image data, other identification information, or the identification information attached to the buffer unit 110 that the input image data is the same. The image detection unit 125 determines the detection result of the previous window frame acquired from the storage unit 105 (step S36). If it is determined that the previous window frame is present (step S36: Yes), the input image data is all It is a screen image, and it is determined that the PC 13 is displaying the full screen (step S37). That is, since there is no window frame in the input image data and there was a window frame in the previous process, it is determined that the PC 13 has switched from the window frame display state to the full screen display.

  On the other hand, if it is determined that there is no window frame last time (step S36: No), the image detection unit 125 further determines whether the previous (previous) determination result is a full-screen image or a frame image (step S38). . If it is determined that the image is a full screen image (step S38: Yes), the image detection unit 125 determines that the input image data is a full screen image (step S37). That is, since the window frame is not detected from the input image data in which the window frame has been detected previously, it is determined that the PC 13 has switched from the display state of the window frame to the full screen display.

If it is determined that the frame image has been determined in the previous and previous determinations (step S38: No), the image detection unit 125 indicates that the input image data is a frame image, and all PCs 13 that have transmitted the input image data have received the input image data. It is determined that the screen is not being displayed (step S34). That is, the PC 13 determines that a window frame of an application program that does not store features in the storage unit 105 is displayed.
When the image detection unit 125 determines that the window frame detection processing for all the PCs 13 has been completed (step S39: Yes), the processing of FIG. 6 ends.
According to the processing of FIG. 6, when an application program storing features in the storage unit 105, that is, a supported application program is used on the PC 13 and displayed on the full screen on the PC 13, the projector 11 displays the entire area. The status can be displayed.

  As described above, the projector 11 according to the embodiment to which the invention is applied divides the projection unit 3 that displays input image data input from the PC 13 and the display area on the screen SC into a plurality of areas. Display control for switching between a divided display state in which a plurality of input image data input from each of a plurality of PCs 13 is displayed in each area and an entire area display state in which any one input image data is displayed in the entire display area Unit 107 and an image detection unit 125 that detects that any one of the input image data is in a predetermined state. The display control unit 107 determines whether any one of the input image data is in a predetermined state by the image detection unit 125. Is detected, the detected input image data is displayed in the entire area display state by the projection unit 3. As a result, when any one of the input image data input from the plurality of PCs 13 is in a predetermined state, the input image data is displayed in the entire display area. The display state can be easily switched and desired input image data can be displayed in the entire display area without performing an instruction operation or an operation for designating input image data to be displayed in the entire display area.

In addition, the image detection unit 125 may determine whether the input image data is a frame image in which a window frame is provided in the image and an object is displayed in the window frame, or the object is the entire image without the window frame in the image. If it is a full-screen image, it is detected that this input image data is in a predetermined state. Therefore, the input image data input from the PC 13 has a window frame. If there is no full screen image, this input image data is displayed in the entire display area. Therefore, by simply controlling the state of the image output by the PC 13, that is, the display state on the monitor 14 of the PC 13, the display state of the projector 11 can be switched to display desired input image data over the entire display area.
For example, the image displayed on the screen SC by the projector 11 can be switched to the full area display state simply by performing a simple operation of displaying the image in the full screen on the PC 13 or displaying the image in the slide show format.

  Further, the image detection unit 125 detects that the input image data detected as being in the predetermined state is no longer in the predetermined state, and the display control unit 107 switches from the entire region display state to the split display state. Thus, it is possible to easily return to the split display state without performing an operation for instructing switching to the split display state.

In addition, the display control unit 107 newly sets a predetermined value when the image detection unit 125 detects that the input image data input from another PC 13 is in a predetermined state during display in the entire region display state. Since the input image data detected to be in the state is displayed in the entire area display state, it is possible to control the state of the image output by the PC 13 without performing an operation to instruct switching of the input image data. The image displayed on the entire display area of the screen SC can be switched.
Further, the projector 11 includes an I / F 101 as a digital interface to which input image data is input from the PC 13, and displays the digital image data input from the PC 13 via the I / F 101, so that the image quality is deteriorated. In addition, it is possible to easily detect that the input image data is in a predetermined state by digital processing.

  In addition, embodiment mentioned above does not limit this invention, It is also possible to apply this invention as an aspect different from the said embodiment. For example, in the above-described embodiment, images input from four PCs 13 connected to the projector 11 are displayed side by side, or an image input from any one of the four units is displayed in full screen alone. Although the case has been described as an example, the projector 11 may be connected to a smaller number or a larger number of PCs 13 than four, and the input image data to be displayed in a divided display state on the screen SC may be appropriately selected. Furthermore, the display device of the present invention is not limited to the projector that projects an image on the screen SC, but a liquid crystal monitor or liquid crystal television that displays an image on a liquid crystal display panel, or a monitor that displays an image on a PDP (plasma display panel). Self-luminous display devices such as devices or television receivers, monitor devices that display images on an organic EL display panel called OLED (Organic Light-emitting-diode), OEL (Organic Electro-Luminescence), etc. Various direct-view display devices are also included in the display device of the present invention, and a portable display device that can display an image based on an input image signal in color is also included. In this case, a liquid crystal display panel, a plasma display panel, and an organic EL display panel correspond to the modulation means. Note that when the display device is a direct-view display device such as a liquid crystal television, the display region indicates the region for displaying an image included in the display device.

  For example, in the above-described embodiment, the configuration using three transmissive or reflective liquid crystal panels 32 corresponding to each color of RGB as an example of a modulation unit that modulates light emitted from the light source has been described. The present invention is not limited to this, for example, a system using a single liquid crystal panel and a color wheel, a system using three digital mirror devices (DMD), a single digital mirror device and a color wheel. You may comprise by the system etc. which combined. Here, when only one liquid crystal panel or DMD is used as the modulation unit, a member corresponding to a synthetic optical system such as a cross dichroic prism is unnecessary. In addition to the liquid crystal panel and the DMD, any configuration that can modulate the light emitted from the light source can be used without any problem.

  Further, the control program stored in the storage unit 105 in the above embodiment and the detection result of each function of the display control unit 107 may be stored in a non-illustrated nonvolatile memory, or may be a portable type. The configuration may be stored in a recording medium, or the projector 11 may be stored in a downloadable manner in another device connected via a communication network. In addition, each functional unit of the projector 11 illustrated in FIG. 1 indicates a functional configuration, and a specific mounting form is not particularly limited. That is, it is not always necessary to mount hardware corresponding to each function unit individually, and it is of course possible to adopt a configuration in which the functions of a plurality of function units are realized by one processor executing a program. In addition, in the above embodiment, a part of the function realized by software may be realized by hardware, or a part of the function realized by hardware may be realized by software. In addition, the specific detailed configuration of the projector 11 can be arbitrarily changed without departing from the gist of the present invention.

  DESCRIPTION OF SYMBOLS 3 ... Projection part (display means), 10 ... Display system, 11 ... Projector (display apparatus), 14 ... Monitor, 13 ... PC (image supply apparatus), 17 ... Communication network, 101 ... I / F (digital interface), DESCRIPTION OF SYMBOLS 103 ... Control part, 105 ... Memory | storage part, 107 ... Display control part (display control means), 110 ... Buffer part, 110A ... Image buffer, 125 ... Image detection part (image detection means), 126 ... Screen division | segmentation process part, 127 ... Image generation unit, 131 ... CPU, 136 ... Display unit, 200, 210 ... Projection image, 201 ... Area, 220 ... Frame image, 230 ... Full screen image, SC ... Screen.

Claims (7)

A display device that displays an input image input from an image supply device,
Display means for displaying the input image;
The display area of the display means is divided into a plurality of areas, and a divided display state in which the plurality of input images input from each of the plurality of image supply devices is displayed in each of the divided areas, Display control means for switching between the entire area display state for displaying the input image in the entire display area;
Image detecting means for detecting that any one of the input images is in a predetermined state,
The display control means causes the display means to display the detected input image in the full area display state when any of the input images is detected to be in a predetermined state by the image detection means. thing,
A display device.   The image detection means may be configured such that the input image is a frame image in which a window frame is provided in the image and an object is displayed in the window frame, or an object is displayed on the entire image without the window frame in the image. The display device according to claim 1, wherein it is determined whether the input image is a full screen image, and if the input image is a full screen image, it is detected that the input image is in the predetermined state. The image detecting means detects that the input image detected to be in the predetermined state is no longer in the predetermined state;
The display control means switches from the whole area display state to the divided display state when the input image being displayed in the whole area display state is detected to be no longer in the predetermined state by the image detection means. The display device according to claim 1 or 2.   The display control means is configured to display one of the input images from the other image supply device by the image detection means while the input image is being displayed in the whole area display state by the display means. 4. The input image that is newly detected to be in the predetermined state is displayed in the entire area display state when it is detected that The display device described.   5. The display device according to claim 1, further comprising a digital interface through which the input image is input from the image supply device, wherein digital image data is input through the digital interface. A control method for a display device comprising display means for displaying an input image input from an image supply device,
A divided display state in which the display area displayed by the display unit is divided into a plurality of areas, and the plurality of input images input from each of the plurality of image supply devices are displayed in each of the divided areas. Switching between the whole area display state for displaying the two input images in the whole display area,
When it is detected that any of the input images is in a predetermined state, the detected input image is displayed in the whole area display state by the display means. A computer-executable program for controlling a display device having display means for displaying an input image input from an image supply device,
The computer,
Image detecting means for detecting that any one of the input images is in a predetermined state;
A divided display state in which the display area displayed by the display unit is divided into a plurality of areas, and the plurality of input images input from each of the plurality of image supply devices are displayed in each of the divided areas. The input image detected when the input detection image is detected to be in a predetermined state by switching between the entire region display state in which the two input images are displayed in the entire display region. Display control means for displaying in the entire area display state by the display means,
A program characterized by making it function.

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