JP2013167881A - Image display unit and control method of image display unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of reducing labor for utilizing an image display unit.SOLUTION: The image display unit is connected to a general purpose interface of an image supply device. A device kind of the image display unit is identified by the image supply device as a specified general purpose device which is not an image display device. Then, the image supply device transmits an image for display to the image supply device identified as the general purpose device. The image display unit receives and displays the image as the general purpose device.

Description

  The present invention relates to communication between an image supply device and an image display device.

  Conventionally, various peripheral devices such as a data storage device, an input device, and an image display device are connected to a computer and used. A USB (Universal Serial Bus) interface is often used as a general-purpose interface for easily connecting such various peripheral devices (see, for example, Patent Document 1).

JP 2004-69996 A

  Incidentally, in order to perform data communication between a computer and a peripheral device connected via an interface, a communication protocol suitable for the type of the peripheral device is used. For example, when an image display device such as a projector is connected to such a general-purpose interface instead of an interface dedicated to image signals, a dedicated communication protocol that is different for each model of the image display device is used. .

  However, various operations have been required to use an interface control program (also called a device driver) for such a dedicated protocol. For example, the user has installed such a dedicated driver on the computer. Further, manufacturers of image display devices have newly developed such dedicated drivers. Thus, a great deal of effort has been required to use the image display device.

  Such a problem is not limited to the USB interface, but is a problem common to general-purpose interfaces that can be arbitrarily connected to a plurality of types of general-purpose devices. Such a problem is not limited to the case where an image display device is connected to a computer, and is generally a problem common to systems that supply and display images from an image supply device to an image display device via an interface. .

  SUMMARY An advantage of some aspects of the invention is that it provides a technique capable of reducing labor for using an image display device.

  In order to solve at least a part of the problems described above, the image display apparatus according to the first aspect of the present invention is connected to a general-purpose interface that is an interface of an image supply apparatus and can be arbitrarily connected to a plurality of types of general-purpose devices. And an image display device that sequentially displays images based on a plurality of image data sequentially supplied from the image supply device, the communication control unit controlling data communication via the interface, and the image An image display unit that displays an image based on the data, and the communication control unit, as the identification information indicating the device type of the image display device, for the start of the data communication, a specific that is not an image display device Identification information indicating a general-purpose device is transmitted to the image supply device, and the communication control unit transmits the image supply device as the general-purpose device. Which receives the image data from, and supplies to the image display unit for displaying the received image data.

  According to this image display apparatus, since the image display apparatus is identified as a general-purpose device, data communication between the image supply apparatus and the image display apparatus can be easily performed. As a result, labor for using the image display device can be reduced.

  Here, it is preferable that the interface is a USB interface, and the identification information is set to a mass storage class.

  The USB interface is easy to connect between devices and can be used easily. The mass storage class is designed so that the data transfer rate to the data storage device does not become excessively slow in order to quickly write data to the data storage device. Therefore, it is possible to transfer image data quickly.

  The image display device further includes a data storage unit accessible by the image supply device, and the communication control unit is (i) a communication command used in communication by the mass storage class, When the communication command for receiving the data is received, the received data is supplied to the data storage unit. (Ii) When the predetermined communication command different from the communication command for reading data is received, the received data Is preferably supplied to the image display unit as image data.

  According to this configuration, the image display device can receive the image data and provide various data stored in the data storage unit to the image supply device.

  Further, the data storage unit preferably stores an image transfer program for causing a computer to realize a function of transmitting the image data to the image display device using communication by the mass storage class.

  According to this configuration, a program for transmitting image data to the image display device can be easily provided to the image supply device, so that the labor for using the image display device can be reduced.

  In the image display device, the image transfer program is configured to display on the image display device an image in which only a partial area of the current image to be displayed by the transmitted image data is changed. It is preferable to cause the computer to realize a function of transmitting updated image data representing only a part of the area including the changed area.

  According to this configuration, when an image in which only a part of the area has changed is displayed on the image display device, only the part of the area including the changed area is transmitted. The amount of data transferred between the two can be reduced. As a result, it is possible to increase the update frequency of images displayed by the image display device.

  In each of the image display devices described above, when the image display unit receives updated image data representing only a partial region of the current image to be displayed by the received image data, only the partial region is received. Is preferably updated.

  According to this configuration, when an image in which only a part of the area has changed is displayed on the image display apparatus, only the part of the area including the changed area needs to be transmitted. The amount of data transferred to and from can be reduced. As a result, it is possible to increase the update frequency of images displayed by the image display device.

  In addition, the image supply apparatus according to the second aspect of the present invention supplies a plurality of image data in order to an image display apparatus that receives image data as a specific general-purpose device that is not an image display device, and sequentially displays the images. A general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices, and identifies the device type of the image display device as the general-purpose device By controlling the communication control unit that controls data communication through the interface, and controlling the communication control unit, the image data for the display is identified as the general-purpose device that is not an image display device. And an image transfer processing module for transmitting to the image display device.

  According to this image supply apparatus, since the image display apparatus is identified as a general-purpose device, data communication between the image supply apparatus and the image display apparatus can be easily performed. As a result, labor for using the image display device can be reduced.

  In the image supply device, it is preferable that the interface is a USB interface, and the communication control unit identifies a device type of the image display device as a mass storage class.

  The USB interface is easy to connect between devices and can be used easily. The mass storage class is designed so that the data transfer rate to the data storage device does not become excessively slow in order to quickly write data to the data storage device. Therefore, it is possible to transfer image data quickly.

  In the image supply device, the image display device further includes a data storage unit accessible by the image supply device, and the image supply device further includes a communication command used in communication by the mass storage class. A data reading module for reading data stored in the data storage unit by using a communication command for data reading, wherein the image transfer processing module is different from the communication command for data reading. It is preferable to transmit the image data by using the communication command.

  According to this configuration, the image supply device can transmit the image data and use various data stored in the data storage unit.

  In each of the image supply devices, the image transfer processing module is configured to display on the image display device an image in which only a partial area of the current image to be displayed by the transmitted image data is changed. It is preferable to have a function of transmitting updated image data representing only a part of the current image including the changed region.

  According to this configuration, when an image in which only a part of the area has changed is displayed on the image display device, only the part of the area including the changed area is transmitted. The amount of data transferred between the two can be reduced. As a result, it is possible to increase the update frequency of images displayed by the image display device.

  In the image supply device, an application program capable of issuing an image drawing command, a drawing module for processing the drawing command issued by the application program, and a specific drawing command issued by the application program A hook processing module that pre-hooks and draws an image in a specific transfer image storage area in the general-purpose memory in accordance with the acquired drawing command, and the image transfer processing module includes an image from the transfer image storage area. The hook processing module has a function of transferring the acquired image to the image display device via the interface, and the hook processing module stores an image in accordance with the specific drawing command in the transfer image storage area. A first indicating a first change region that is a region to be drawn And a function for supplying the drawing command to the drawing module after processing the specific drawing command, the drawing module having the application program or the hook process A function of drawing an image in a frame memory in accordance with a drawing command received from the module, and a second change area indicating a second change area in the frame memory in which an image is drawn in accordance with the drawing command A function of writing information into the general-purpose memory, and the image transfer processing module refers to the first and second change area information stored in the general-purpose memory, and An image portion corresponding to an area not included in the first change area among the two change areas is acquired from the frame memory; and (ii) the first change area An image portion corresponding to the change area is acquired from the transfer image storage area without acquiring from the frame memory, and (iii) the screen update that is the sum of the first and second change areas is acquired. The screen update area information indicating the area may be transferred to the image display device via the interface.

  According to this configuration, when a specific drawing command is issued, the hook processing module hooks and acquires the drawing command instead of the drawing module and draws the image in the general-purpose memory. Compared with the case where the entire image is transferred from the VRAM to the RAM (general purpose memory), the speed of the entire transfer process can be improved. Of the second change area, the area not included in the first change area is an area that is not drawn by the hook processing module. Since the image of this area is acquired from the frame memory, the image is not lost. Can be transferred.

  In the image supply device, an application program capable of issuing an image drawing command, a drawing module for processing the drawing command issued by the application program, and a specific drawing command issued by the application program A hook processing module that pre-hooks and draws an image in a specific transfer image storage area in the general-purpose memory in accordance with the acquired drawing command, and the image transfer processing module includes an image from the transfer image storage area. The hook processing module has a function of transferring the acquired image to the image display device via the interface, and the hook processing module stores an image in accordance with the specific drawing command in the transfer image storage area. A first indicating a first change region that is a region to be drawn And a function for supplying the drawing command to the drawing module after processing the specific drawing command, the drawing module having the application program or the hook process A function of drawing an image in a frame memory in accordance with a drawing command received from the module, and a second change area indicating a second change area in the frame memory in which an image is drawn in accordance with the drawing command A function of writing information into the general-purpose memory, and the image transfer processing module refers to the first and second change area information stored in the general-purpose memory, and An image portion corresponding to an area not included in the first change area among the two change areas is acquired from the frame memory; and (ii) the second change area An image portion corresponding to a region included in the first change region among the change regions is acquired from the transfer image storage region without acquiring from the frame memory, and (iii) the acquired image portion is The screen update area information indicating the screen update area that is the same as the second change area may be transferred to the image display apparatus via the interface.

  According to this configuration, when a specific drawing command is issued, the hook processing module hooks and acquires the drawing command instead of the drawing module and draws the image in the general-purpose memory. Compared with the case where the entire image is transferred from the VRAM to the RAM (general purpose memory), the speed of the entire transfer process can be improved.

  The present invention can be realized in various forms, for example, an image display system, an image supply device and an image display device that constitute the image display system, a hook processing module and an image transfer used in the image supply device. The present invention can be realized in various modes such as a processing module, an image supply method and an image display method, a computer program for realizing the method or apparatus, and a recording medium on which the computer program is recorded.

1 is an explanatory diagram showing a configuration of an image display system as an embodiment of the present invention. FIG. 2 is a block diagram showing an internal configuration of a computer 100 and a projector 200. Explanatory drawing which shows the detail of the software structure in 1st Example. 6 is a flowchart showing a procedure of connection processing executed when the projector 200 is connected to the computer 100. The flowchart which shows the procedure of an image display process. Explanatory drawing which shows an example of D9 command. 9 is a flowchart showing a procedure of image display processing in the second embodiment. 12 is a flowchart showing a specific procedure of an example of image display processing in the second embodiment. Explanatory drawing which shows the detail of the software structure in 3rd Example. The flowchart which shows the procedure of the connection process in 3rd Example. 10 is a flowchart showing a procedure of image display processing in the third embodiment. Explanatory drawing which shows the hierarchical structure of the software and hardware of a computer for capturing the change part in a screen. Explanatory drawing which shows the example of the change area information and image data storage area in an Example. 10 is a flowchart showing operations of a hook processing module 400 and an image transfer program 500a in the third embodiment. The flowchart which shows the detailed procedure of step S20. Explanatory drawing which shows the relationship between the change area | region and screen update area | region in 3rd Example. Explanatory drawing which shows the content of the optimization process of a screen update area | region. The flowchart which shows the detailed procedure of step S22. Explanatory drawing which shows the relationship between the change area | region and screen update area | region in 4th Example. The flowchart which shows the procedure of the process according to the request | requirement of the projector 200a.

Next, embodiments of the present invention will be described in the following order based on examples.
A. First embodiment:
B. Second embodiment:
C. Third embodiment:
D. Fourth embodiment:
E. Example 5:
F. Variations:

A. First embodiment:
FIG. 1 is an explanatory diagram showing the configuration of an image display system as an embodiment of the present invention. The image display system 10 of the present embodiment includes a personal computer 100 (hereinafter also referred to as “PC 100”) as an image supply device, a projector 200 as an image display device, a USB cable 300 that connects the computer 100 and the projector 200, and It has. The computer 100 has a function of supplying an image through the USB cable 300 to the projector 200, causing the projector 200 to project the image, and displaying the image on the projection display screen 70.

  FIG. 2 is a block diagram showing the internal configuration of the computer 100 and the projector 200. The computer 100 includes a CPU 102, a ROM 104, a RAM 106 as a general-purpose memory (also referred to as “system memory”), a hard disk drive 108, an input unit 110 including a keyboard and a pointing device, a USB interface unit 112, A VRAM 114 as a frame memory, a graphic controller 116, a display device 118 such as a liquid crystal display, and a bus 120 for connecting these elements are provided.

  The RAM 106 includes an application program 122, a graphical device interface (GDI) 124, a display driver 126, a file system module 130, a SCSI driver 132, a mass storage driver 134, a USB module 136, an image, and the like. Various computer programs including the transfer program 500 are stored. The GDI 124, the display driver 126, the file system module 130, the SCSI driver 132, the mass storage driver 134, and the USB module 136 function as a part of the operating system (OS). In this embodiment, Windows (registered trademark) provided by Microsoft Corporation is assumed as the operating system. Such various computer programs are provided in a form recorded on a computer-readable recording medium such as a flexible disk or a CD-ROM.

  The GDI 124 is a computer program that uniformly manages drawing on a display device (for example, the display device 118 of the computer 100) or a printing device (not shown). As is well known, the GDI 124 provides an application program interface (API: Application Program Interface) relating to drawing called “GDI function” to various application programs. Note that an API generally refers to a collection of procedures for an application program to use various functions of an operating system.

  For example, the application program 122 issues a drawing request for a presentation sheet image included in the presentation file to the GDI 124. Usually, the drawing request also includes information regarding the output destination of the image (that is, information specifying whether to output the image to the display device or the printing device). The GDI 124 receives the drawing request issued from the application program 122, checks the output destination of the image based on the drawing request, and passes the drawing request to the display driver 126 if the output destination is a display device. The display driver 126 draws image data in the VRAM 114 in accordance with the received drawing request.

  Other components of the computer 100 will be described later.

  On the other hand, the projector 200 includes a CPU 202, a ROM 204, a RAM 206, an input unit 210 including various operation buttons, a USB interface unit 212, an image processing unit 214, a light source lamp, a liquid crystal panel, and a projection optical system. A section 216 and a bus 218 for connecting these elements. The ROM 204 includes an image display module 240, a disk image 224, a command dispatcher module 226 (hereinafter also simply referred to as “dispatcher 226”), a data management module 230, a SCSI driver 232, a mass storage driver 234, a USB Various computer programs including the module 236 are stored.

  FIG. 3 is an explanatory diagram showing details of the software configuration in the first embodiment. In FIG. 3, the components are arranged in the same order as the data communication hierarchy. The USB modules 136 and 236 perform data communication by controlling the USB interface units 112 and 212 (FIG. 2) and interpreting the USB protocol, respectively. The mass storage drivers 134 and 234 provided in the upper layers of the USB modules 136 and 236 perform data communication according to a mass storage class communication protocol. The SCSI drivers 132 and 232 provided in the upper layers of the mass storage drivers 134 and 234 perform data communication using a SCSI command set. The file system module 130 of the computer 100 manages the file system by issuing a data access request to the SCSI driver 132. On the other hand, the data management module 230 of the projector 200 receives an access request from the computer 100 via the dispatcher 226 and the SCSI driver 232 and relays access to the disk image 224 in response to this request.

  FIG. 3 also shows detailed configurations of the image transfer program 500 and the image display module 240. The image transfer program 500 includes a capture module 510, a data generation module 520, and a SCSI wrapper module 530. The image display module 240 includes an image development module 242 and a data acquisition module 244. Details of these will be described later.

  FIG. 4 is a flowchart showing a procedure of connection processing executed when the projector 200 is connected to the computer 100. First, the projector 200 operates as a CD-ROM drive by the SCSI driver 232 (FIG. 3), the mass storage driver 234, and the USB module 236 (step S100).

  Next, the USB module 136 of the computer 100 detects that the projector 200 is connected to the computer 100 via the USB cable 300 (step S104), and requests apparatus configuration information from the projector 200 in response to this detection (step S104). Step S108).

  In response to this request, the USB module 236 of the projector 200 transmits device configuration information to the computer 100 (step S112). The transmitted device configuration information includes information indicating that the projector 200 operates as a data storage device conforming to the USB standard. Specifically, the device configuration information includes information indicating that the device class (interface class) of the USB device is “mass storage class”. As is well known, the command set available in the “mass storage class” is specified by the interface subclass. The projector 200 of the first embodiment is assumed to be compatible with “SCSI command set”. Therefore, the device configuration information includes information indicating that the subclass is “SCSI command set”. Various other classes (for example, “ATAPI”) can be adopted as the subclass. The device configuration information also includes other various USB descriptors.

  The USB module 136 of the computer 100 (FIG. 3) identifies the projector 200 as a device that is classified into the mass storage class in response to receiving this device configuration information, and is normally provided in the OS. A general-purpose mass storage driver 134 is loaded (step S116). The mass storage driver 134 is incorporated in the operating OS process. Accordingly, the computer 100 can perform data communication with the projector 200 by using the mass storage driver 134.

  The mass storage driver 134 corresponds to a USB class driver. The class driver is a communication control module that is located in an upper layer of a USB bus driver (USB module 136 in the example of FIG. 3) and performs communication with the USB device according to a communication protocol corresponding to the type of the USB device. In the USB standard, USB device types are classified into a plurality of classes. Different communication protocols are used for each class (that is, for each device type). Here, it is also possible to define a vendor-specific class (Vendor Specific Class) so that a USB device having various functions can be used. In this case, a dedicated communication protocol (that is, a dedicated class driver) is used.

  On the other hand, for some representative classes, communication protocols are standardized in order to facilitate data communication between devices. The “mass storage class” is one of such classes. The mass storage driver 134 performs data communication according to a mass storage class communication protocol. Such a mass storage driver 134 is not limited to a specific manufacturer's data storage device, but is shared by various manufacturers' data storage devices (for example, CD-ROM drive, DVD-ROM drive, hard disk drive, semiconductor memory). Is done. Similarly, a general-purpose data storage device (for example, a CD-ROM drive) using a standardized communication protocol is not limited to a specific manufacturer's computer, but various manufacturers' computers (for example, personal computers and portable information devices). It can be commonly used for terminals.

  In this embodiment, the SCSI driver 132 is loaded together with the mass storage driver 134 (FIG. 3). At this time, the SCSI driver 132 acquires information indicating that the projector 200 is a CD-ROM drive from the SCSI driver 232 of the projector 200. Thus, the file system module 130 can use the projector 200 (disk image 224) as a CD-ROM drive by transmitting a SCSI command to the projector 200 via the SCSI driver 132. The projector 200 is not limited to a CD-ROM drive, and may be identified as various data storage devices (for example, a DVD-ROM drive or a hard disk drive). In either case, data reading from the disk image 224 is performed by the file system module 130 and the SCSI driver 132. Thus, the entire file system module 130 and SCSI driver 132 correspond to the “data read module” in the present invention.

  In the next step S120, the computer 100 executes an autorun program stored in the projector 200 recognized as a CD-ROM drive. Thereby, the image transfer program 500 recorded on the disk image 224 (FIG. 3) is transmitted from the projector 200 to the computer 100 (step S124), and the image transfer program 500 is started (step S128). If a file “Autorun.inf” is recorded in the root folder of the CD-ROM, the Windows operating system executes an arbitrary program specified by this file. Therefore, in this embodiment, this function is used to execute the image transfer program 500 recorded on the disk image 224.

  Depending on the settings of the operating system, the auto-run program automatic execution function may be disabled. Also, some operating systems cannot use the automatic execution function. In such a case, the computer 100 may acquire the image transfer program 500 from the projector 200 (disk image 224) in accordance with a user instruction. Further, instead of the image transfer program 500 stored in the projector 200, an image transfer program 500 recorded on a recording medium such as another CD-ROM or an image transfer program 500 downloaded from the Internet may be used.

  The activated image transfer program 500 starts image display processing using the projector 200. FIG. 5 is a flowchart showing a procedure of image display processing. In the first step S200, the capture module 510 (FIG. 3) captures the image displayed by the display device 118 (FIG. 2). Any method can be employed as the image capturing method. For example, a GDI function for capturing an image may be called, or another drawing API may be used. Further, the capture module 510 may directly acquire image data from the VRAM 114. In the first embodiment, the entire display screen displayed by the display device 118 is captured.

  In the next step S204, the data generation module 520 generates display data using the captured image data acquired by the capture. In the first embodiment, display data is generated by compressing captured image data. Any compression algorithm can be used. However, display data may be generated without compression. The same applies to other embodiments described later.

  Next, the data generation module 520 issues an instruction to transmit display data to the SCSI wrapper module 530. In response to this instruction, the SCSI wrapper module 530 generates a special SCSI command (hereinafter also referred to as “D9 command”) for transmitting display data. FIG. 6 is an explanatory diagram showing an example of the D9 command. The D9 command conforms to the structure of a command descriptor block (CDB: Command Descriptor Block) defined by SCSI regulations. This is because data communication with the projector 200 is performed by using the mass storage driver 134 as in the case of the SCSI driver 132 (FIG. 3).

  The 0th byte represents an operation code (hereinafter also referred to as “OP code”). The OP code is a code for identifying a command, and a predetermined code is assigned in advance for each command such as “read” and “write”. In the first embodiment, the SCSI command issued by the image transfer program 500 is assigned “D9h (h means hexadecimal notation; the same applies hereinafter)”. Accordingly, when the OP code is “D9h”, it can be determined that the command is issued by the image transfer program 500. If the OP code is other than “D9h”, it can be determined that the command is issued by the SCSI driver 132.

  The OP code for identifying the SCSI command issued by the image transfer program 500 is not limited to “D9h”, and an arbitrary code can be adopted. However, it is preferable to adopt a code different from the code of the SCSI command for reading the data of the disk image 224. By doing so, it is possible to achieve both the transfer of image data and the reading of the disk image 224. Note that the data read command means a command used for a series of processes from connection of the data storage device to the interface to establishment of communication until completion of data read. Such commands include, for example, an inquiry command and a read command.

  The second byte represents a UD command code. The UD command code is a code for identifying specific contents of a command issued by the image transfer program 500. When the image transfer program 500 issues a plurality of types of commands, these commands are identified by the UD command code. Therefore, the command issued by the image transfer program 500 can be identified by the combination of the OP code and the UD command code. However, when the command issued by the image transfer program 500 is only an image data transmission command, the UD command code may be omitted.

  The third to sixth bytes represent the data size to be transmitted. This data size means the size of data transmitted following the SCSI command. As will be described later, since the display data is transmitted following this D9 command, the data size is set to the size of the display data.

  The seventh byte represents a CE flag. The CE flag is a flag indicating whether or not the transmitted data is continued. Data may be divided into a plurality of partial data for transmission. In this case, the CE flag is set to “E (end)” in the D9 command for transmitting the last partial data, and the CE flag is set to “C (continuation) in the D9 command for transmitting other partial data. "Is set. When data is transmitted without being divided, the CE flag is set to “E”.

  The other part of the D9 command is set to a predetermined value. These values are used for data communication in accordance with SCSI regulations (details are omitted).

  When the D9 command is generated, the SCSI wrapper module 530 issues an instruction for transmitting the D9 command (CDB) and display data to the mass storage driver 134. Then, the mass storage driver 134 generates a command block wrapper (CBW: Command Block Wrapper) for transmitting the D9 command. The CBW is data for transmitting a SCSI command using a mass storage class, and stores a CDB. Then, the mass storage driver 134 controls the USB module 136 to transmit the CBW and the display data in this order.

  FIG. 5 shows CBW and display data TD to be transmitted. The display data TD includes a header ImgH and compressed image data ImgD. The header ImgH includes information representing the compression format (algorithm), the height (number of dots) and width (number of dots) of the image, and the position of the image in the screen. The position in the screen is represented, for example, by the position in the screen of the reference point (usually the upper left corner dot) of the image represented by the image data ImgD. In the first embodiment, the display data TD is transmitted without being divided.

  The computer 100 repeatedly executes the above-described image capture (S200), transmission of CBW (D9 command) and display data TD (S204).

  On the other hand, in the projector 200, the CBW (D9 command) and the display data TD are received by the USB module 236 and the mass storage driver 234 (step S220). In the next step S224, the dispatcher 226 determines whether or not the OP code of the SCSI command stored in the CBW is “D9h”. If the OP code is “D9h”, the dispatcher 226 supplies the received data to the data acquisition module 244 in the next step S230. The supplied data includes a SCSI command and data transmitted together with the command (that is, CBW and display data TD). In the next step S234, the data acquisition module 244 extracts the display data TD and supplies it to the image development module 242. The image expansion module 242 expands the image data ImgD according to the compression format specified by the header ImgH. Then, the image development module 242 controls the image processing unit 214 (FIG. 2) according to the information (height, width, position) of the header ImgH and the decompressed image data. The image data is developed in a display memory (not shown). At this time, the image development module 242 may execute resolution conversion processing according to the resolution (number of pixels) of the projection unit 216 and the information of the header ImgH.

  As a result, the projector 200 can display an image on the projection display screen 70 as shown in FIG. Thus, the image display module 240 displays an image in response to the projector 200 receiving the image data. Therefore, when the computer 100 repeatedly transmits image data, the image displayed by the projector 200 is also repeatedly updated.

  In the next step S238, the data acquisition module 244 issues an instruction to the mass storage driver 234 to transmit a response indicating that the display data TD has been normally received. Then, the mass storage driver 234 generates a command status wrapper (CSW: Command Status Wrapper) for transmitting a response. The CSW is data for transmitting a SCSI status response using the mass storage class. The mass storage driver 234 transmits the CSW by controlling the USB module 236.

  On the other hand, when the OP code is different from “D9h” (S224: No), the dispatcher 226 supplies the received data to the SCSI driver 232 in the next step S290. The supplied data includes a SCSI command and data transmitted together with the command. However, when only the SCSI command is received, only the SCSI command is supplied (for example, when a READ command is issued). In the next step S294, the data management module 230 relays access to the disk image 224 in accordance with the SCSI command received via the SCSI driver 232 (eg, data stored in the disk image 224 is transmitted to the computer 100). ). The entire SCSI driver 232, data management module 230, and disk image 224 correspond to the “data storage unit” in the present invention.

  In the next step S298, the data management module 230 transmits a status response representing the execution result of the command to the computer 100. This process is performed similarly to step S238. When the image transfer program 500 is transmitted to the computer 100, the processes in steps S290 to S298 are executed.

  As described above, the first embodiment has the following various features and advantages. The first feature point is that the projector 200 is identified as a general-purpose device (mass storage class) different from the projector. The USB module 236 of the projector 200 transmits identification information (device class (interface class)) indicating such a general-purpose device to the computer 100. As a result, data communication (image data transfer) via the USB interface units 112 and 212 can be performed using the general-purpose mass storage driver 134 without installing a dedicated device driver for the projector 200 in the computer 100. There is an advantage that it becomes possible. The entire USB module 236, mass storage driver 234, and dispatcher 226 in the projector 200 correspond to the “communication control unit of the image display device” in the present invention. On the other hand, the entire USB module 136 and mass storage driver 134 in the computer 100 correspond to the “communication control unit of the image supply apparatus” in the present invention.

  The second feature point is that the projector 200 is identified as a data storage device (mass storage class). The mass storage class communication protocol is designed so that the data transfer rate to the data storage device does not become excessively slow. Therefore, it is possible to increase the transfer rate of the image data and increase the frequency of updating the display image by the projector 200.

  A third feature point is that the image transfer program 500 is stored in the data storage unit (disk image 224) of the projector 200. Thereby, the image transfer program 500 can be easily provided to the computer 100. As a result, the preparation of the image transfer program 500 is facilitated, and the convenience relating to the use of the projector 200 can be further improved.

B. Second embodiment:
FIG. 7 is a flowchart showing a procedure of image display processing in the second embodiment. FIG. 7 shows processing executed by the projector 200. In the second embodiment, unlike the first embodiment shown in FIG. 5, the data generation module 520 divides the captured image data into a plurality of partial data, and sequentially transmits them to the projector 200 one by one. The configuration of the apparatus is the same as that of the first embodiment shown in FIGS.

  The processes in steps S220 and S224 are the same as the processes in steps S220 and S224 in FIG. The data acquisition module 244 that has received the D9 command checks the value of the CE flag (FIG. 6) (S228). When the CE flag is set to “C”, the data acquisition module 244 stores the received partial data in the RAM 206 (FIG. 2) (S240) and issues a normal response (S244). This step S244 is the same as step S238 of FIG. Then, the process returns to step S220, and the data acquisition module 244 waits for the remaining partial data.

  When the last partial data of a plurality of partial data is sent, the CE flag is set to “E”. In this case, in the next step S250, the data acquisition module 244 reconstructs the display data by combining the received plurality of partial data, and supplies the display data to the image development module 242. Then, the image development module 242 controls the image processing unit 214 (FIG. 2) according to the header and the image data, as in step S234 of FIG. As a result, the projector 200 displays an image on the projection display screen 70 as shown in FIG. The next step S254 is the same as step S238 in FIG. After step S254, the process returns to step S220. Then, the series of processes described above are repeatedly executed.

  FIG. 8 is a flowchart showing a specific procedure of an example of the image display process in the second embodiment. In this example, the image data is divided into two pieces of partial data and sent.

  The first step S200 is the same as step S200 in FIG. In the next step S208a, the data generation module 520 (FIG. 3) generates the transmission image data ImgD by compressing the captured image data, and generates the first display data TD1 using the image data ImgD. To do. Here, the data generation module 520 divides the image data ImgD into first partial data ImgD1 and second partial data ImgD2. Then, the data generation module 520 generates first display data TD1 including the header ImgH and the first partial data ImgD1.

  Next, the data generation module 520 issues a command for setting the CE flag to “C” and transmitting the first display data TD1 to the SCSI wrapper module 530. In the D9 command (CDB1) generated by the SCSI wrapper module 530, the OP code is set to “D9h” and the CE flag is set to “C”.

  The command block wrapper CBW1 for storing the generated D9 command (CDB1) and the first display data TD1 are transmitted to the projector 200 by the mass storage driver 134.

  On the other hand, in the projector 200 that has received the data, since the CE flag of the received D9 command is set to “C”, a series of processes similar to steps S228, S240, and S244 in FIG. 7 are executed.

  In the computer 100, in response to receiving the normal response (CSW) issued in step S244, the data generation module 520 (FIG. 3) sends an instruction to transmit the remaining second partial data ImgD2 to the SCSI wrapper module 530. It is issued to (S208b). At this time, an instruction to set the CE flag to “E” is issued. In the D9 command (CDB2) generated by the SCSI wrapper module 530, the OP code is set to “D9h” and the CE flag is set to “E”.

  The command block wrapper CBW2 for storing the generated D9 command (CDB2) and the second display data TD2 (second partial data ImgD2) are transmitted to the projector 200 by the mass storage driver 134.

  On the other hand, in the projector 200 that has received the data, since the CE flag of the received D9 command is set to “E”, a series of processes similar to steps S228, S250, and S254 in FIG. 7 are executed.

  As described above, the case where the image data is divided into two pieces of partial data has been described. However, when the image data is divided into three or more pieces of partial data, the partial data is transmitted according to the same procedure. The images are displayed sequentially after all the partial data have been transferred.

  Thus, in the image display process of the second embodiment, the image data is divided and transmitted. Therefore, even when the size of the image data is large, the entire image data can be appropriately transmitted to the projector 200. In particular, depending on the communication interface, there is often an upper limit on the data size that can be transmitted by issuing a single command. Even in such a case, the entire image data can be transferred regardless of the size.

  In the example of FIG. 8, the transmission image data ImgD is divided and transmitted, but various other methods can be employed as a method of dividing and transmitting image data. For example, the display screen may be divided into a plurality of partial screens, and the captured image data may be transmitted for each partial screen. For example, the display screen of the display device 118 may be divided into two partial screens, a left half and a right half. Here, a series of processes for transmitting the image data of the left partial screen to the projector 200, causing the projector 200 to update the left half, and then transmitting the image data of the right partial screen to cause the projector 200 to update the right half. May be repeatedly executed. Here, the projector 200 may update the display after the transfer of the captured image data of the entire display screen is completed. The screen division is not limited to the left half and the right half, and any division can be adopted. Further, it may be divided into three or more regions.

C. Third embodiment:
FIG. 9 is an explanatory diagram showing details of the software configuration in the third embodiment. There are three differences from the first embodiment shown in FIG. The first difference is that the image transfer program 500 a has a determination module 540. The second difference is that the hook processing module 400 and the projector driver 128 are operating on the computer 100a. The third difference is that the state check module 250 is operating on the projector 200a. Other configurations are the same as those of the first embodiment shown in FIG. In the third embodiment, due to these components, only the screen change area is transferred from the computer 100a to the projector 200a. Note that programs 500a, 400, and 128 operating on the computer 100a are stored in the disk image 224. Then, it is transferred from the projector 200a to the computer 100a in accordance with the auto-run program in the connection process shown in FIG. The hardware configuration is the same as that of the first embodiment shown in FIGS.

  FIG. 10 is a flowchart showing the procedure of connection processing in the third embodiment. The process of FIG. 10 is executed after the connection process shown in FIG. This connection process is executed in order for the computer 100a to wait for completion of image data reception preparation by the projector 200a. The reason why the projector 200a waits for completion of reception preparation is as follows. In the third embodiment, as will be described later, after the image data of the entire screen is transmitted for the first time, only the image data of the changed portion of the image is transmitted. Therefore, in order to cause the projector 200a to reliably receive the image data of the entire first screen, the computer 100a waits for the reception preparation completion of the projector 200a.

  In the first step S300, the determination module 540 (FIG. 9) issues a command for transmitting a status inquiry to the projector 200a to the SCSI wrapper module 530. The SCSI wrapper module 530 generates a D9 command for transmitting a status inquiry, similar to the case of transmitting image data. Here, the UD command code (FIG. 6) is set to a code different from the UD command code of the image data transmission command. For example, in the third embodiment, “80h” is adopted for the image data transmission command, and “C1h” is adopted for the command that transmits the status inquiry. The generated D9 command is transmitted to the projector 200a by the mass storage driver 134. When inquiring other various states in addition to the reception state using the D9 command (UD command code = C1h) for this state inquiry, data for identifying the contents of the inquiry subsequent to the D9 command May be sent.

  On the other hand, when the dispatcher 226 of the projector 200a receives the SCSI command (S350), it determines whether the command is a D9 command (S354). If the command is a D9 command, the UD command code is further confirmed (S358). When the UD command code is “C1h”, the received data is supplied to the status check module 250. Although not shown in FIG. 10, when the UD command code is “80h”, the dispatcher 226 uses the received data (image data transmission D9 command and display data) as the data acquisition module 244. To supply.

  The state check module 250 that has received the D9 command (that is, the state inquiry) whose UD command code is set to C1h determines whether or not the state of the projector 200a is a state in which image data can be received (S360). As a condition for determining that reception is possible, any condition indicating that the received image data can be retained without being lost can be employed. For example, the image display module 240 (FIG. 9) may be used on the condition that the activation has been completed. Alternatively, it may be adopted on the condition that the activation of the image processing unit 214 (FIG. 2) has been completed. The state check module 250 stores state data representing the determination result in the RAM 206 (FIG. 2) as data to be transmitted to the computer 100a. In this embodiment, the status data is a character string of either “REDY (reception is possible)” or “BUSY (reception is not possible)”.

  Next, the state check module 250 transmits a response indicating that the state inquiry has been received normally to the computer 100a (S364). This response transmission is performed in the same manner as in step S238 in FIG. At this stage, the status data is not transmitted to the computer 100a. This is because the projector 200a corresponds to the SCSI target and cannot transmit data spontaneously.

  In response to receiving the normal response (CSW) (S304), the determination module 540 of the computer 100a issues a command to send a request inquiry to the SCSI wrapper module 530 (S310). This request inquiry is a command for causing the projector 200a to transmit various data. The SCSI wrapper module 530 generates a D9 command as in the case of transmitting image data. Here, the UD command code (FIG. 6) is set to a code different from both the image data transmission command and the status inquiry transmission command. For example, in the third embodiment, “00h” is adopted for the request inquiry transmission command. The generated D9 command is transmitted to the projector 200a by the mass storage driver 134.

  On the other hand, the dispatcher 226 of the projector 200a supplies the received data to the status check module 250 when the received SCSI command is the D9 command (S354: Yes) and the UD command code is “00h”.

  The state check module 250 that has received the D9 command (that is, the request inquiry) with the UD command code set to 00h sends an instruction to the mass storage driver 234 to transmit the state data stored in the memory in the previous step S360. Issue (S370). The mass storage driver 234 transmits status data to the computer 100a according to the command. In the next step S374, the state check module 250 transmits a response indicating that the data transmission according to the request inquiry has been normally performed to the computer 100a. This response is performed in the same manner as in step S364.

  The status data and response received by the computer 100a are supplied to the determination module 540 (S314, S318). When the status data is “BUSY”, the determination module 540 repeatedly executes a series of processes of steps S300 to S320 until the status data set to “REDY” is received.

  If the status data is “REDY”, the determination module 540 issues an instruction to start the image display process to the modules 510, 520, and 530 in the next step S330.

  FIG. 11 is a flowchart showing the procedure of image display processing in the third embodiment. The processes in the first steps S400, S404, S408, and S412 are the same as steps S200, S204, S234, and S238 in FIG. In particular, in step S400, the entire display screen displayed by the display device 118 is captured. Thereby, the projector 200a can display an image on the projection display screen 70 as shown in FIG. In the flowchart of FIG. 11, the process of confirming the OP code and the UD command code is not shown.

  In the next step S420, the capture module 510 captures only the changed area in the screen. Details of capturing only the change area will be described later. In the next step S424, the captured image data is transmitted from the computer 100a to the projector 200a as in step S404. At this time, the size (height, width) and position in the header are set to values representing the change area.

  In the next step S428, the image development module 242 controls the image processing unit 214 (FIG. 2) according to the header and the image data, as in step S408. At this time, only the image data of the portion representing the change area is updated. Other parts are maintained without being updated. As a result, the projector 200a can display an image in which the change area is updated. The next step S432 is the same as step S412. After step S432, the process returns to step S420. Then, the series of processes in steps S420 to S432 described above are repeatedly executed.

  As described above, in the third embodiment, after the entire display screen is transmitted, only the changed area is transmitted. Further, when only the changed area is received, the image development module 242 updates only the changed area. As a result, the amount of data to be transmitted can be reduced. As a result, the update frequency of the image displayed by the projector 200a can be increased.

  In the example of FIG. 11, the image data for the entire screen is transmitted only once immediately after connection (S400, S404), but the image data for the entire screen may be transmitted a plurality of times after connection. . In this way, it is possible to prevent the image displayed by the projector 200a from being disturbed. For example, the image transfer program 500a may periodically transmit image data of the entire screen. Further, the image transfer program 500a may transmit image data of the entire screen in response to receiving a user instruction.

  Next, the capture of only the changed area (FIG. 11: S420) will be described. FIG. 12 is an explanatory diagram showing a hierarchical structure of computer software and hardware for capturing a changed portion in the screen. The application program 122 and the image transfer program 500a belong to an application program layer (also referred to as “user application program layer”). The GDI 124, the display driver 126, and the projector driver 128 belong to the kernel layer. In addition, the RAM 106 as a general-purpose memory, the USB interface unit 112, the VRAM 114, the graphic controller 116, and the display device 118 belong to a hardware layer.

  A hook processing module 400 is provided between the application program 122 and the GDI 124. The hook processing module 400 hooks a specific drawing command issued by the application program 122 in advance and executes processing described later. Other drawing commands are processed by the GDI 124 as usual. Note that the hook processing module 400 is preferably configured exclusively for each application program so as to hook only a specific drawing command appropriate for the application program 122.

  In the third embodiment, a case where a presentation program (for example, Microsoft PowerPoint) is used as the application program 122 will be described. First, a case where a drawing command is directly passed to the GDI 124 without going through the hook processing module 400 will be described, and then a case where a drawing command is prefetched by the hook processing module 400 will be described.

  For example, the application program 122 issues a drawing request for a presentation sheet image included in the presentation file to the GDI 124. Usually, the drawing request also includes information regarding the output destination of the image (that is, information specifying whether to output the image to the display device or the printing device).

  Note that other general-purpose drawing APIs may be used instead of the GDI 124. The “general-purpose drawing API” means an API that is commonly used for many application programs.

  The GDI 124, the display driver 126, and the projector driver 128 all function as a drawing module that executes a drawing process in accordance with a drawing command. Specifically, the GDI 124 receives the drawing request issued from the application program 122, checks the output destination of the image based on the drawing request, and if the output destination is a display device, the display driver 126 and the projector driver A drawing request is passed to each of 128.

  The display driver 126 draws image data in the VRAM 114 in accordance with the received drawing request. As is well known, the drawing request is not limited to drawing the entire screen, but frequently drawing a part of the screen. When receiving a drawing command for drawing a part of the screen, the display driver 126 draws only an image portion of an area to be drawn (also referred to as “change area”) in the VRAM 114. The graphic controller 116 displays an image on the display device 118 based on image data (that is, bitmap data) drawn in the VRAM 114. On the other hand, the projector driver 128 writes the change area information 106 a indicating the position and size of the drawing target area (that is, the change area) in the VRAM 114 in the RAM 106 in accordance with the drawing request received from the GDI 124. Hereinafter, the change area information written by the projector driver 128 is also referred to as second change area information 106a2 (change area information A2).

  FIGS. 13A and 13B are explanatory diagrams showing examples of the change area information 106a2 and the image data storage area 106b in the RAM 106. FIG. Here, it is assumed that an image to be projected and displayed by the projector changes from FIG. 13A to FIG. 13B. As will be described later, image data transferred from the VRAM 114 by the capture module 510 is stored in the image data storage area 106b. The image data storage area 106b preferably has the same data capacity as the VRAM 114 (frame memory).

  The change area Ra is an area of an image portion drawn by a drawing command when changing the image from FIG. 4 (A) to FIG. 4 (B). The change area information 106a2 regarding the change area Ra includes the x coordinate Xa and the y coordinate Ya of the reference point (usually the upper left point) of the change area Ra, and the width Wa and the height Ha of the change area Ra. The coordinates (Xa, Ya) of the reference point are data indicating the position of the change area Ra, and the width Wa and the height Ha are data indicating the size of the change area Ra.

  The capture module 510 refers to the change area information 106 a 2 in the RAM 106 and transfers the image data in the change area Ra from the VRAM 114 to the image data storage area 106 b in the RAM 106. The image data storage area 106b is a memory area having a size equal to the display resolution of the computer 100 or the projector 200, for example. The capture module 510 further reads the image data of the change area Ra from the image data storage area 106b, and supplies the read image data and the change area information 106a2 to the data generation module 520. The data generation module 520 generates display data (header and image data) using the received data. The generated display data is transmitted to the projector 200a by the mass storage driver 134.

  As described above, when the drawing command is directly passed to the GDI 124 without going through the hook processing module 400, the image data stored in the VRAM 114 is temporarily transferred to the RAM 106, which is a general-purpose memory, and then the image in the RAM 106 is stored. Data is transferred to the projector 200a. For this reason, it takes a considerable time to transfer data from the VRAM 114 to the RAM 106, and a sufficient transfer speed may not be obtained.

  Next, a case where a drawing command is prefetched by the hook processing module 400 will be described. The hook processing module 400 can also be considered as a kind of drawing API, but is distinguished from a general-purpose drawing API such as the GDI 124. That is, the hook processing module 400 is typically configured to process only specific drawing commands, whereas the GDI 124 is configured to process all drawing commands. .

  The hook processing module 400 is loaded (installed) into the application program 122 as a DLL (dynamic link library), for example. In general, an application program operates in units of “processes”. During execution of an application program, multiple modules (GDI32.DLL, Kernel32.DLL, etc.) are loaded in the process, and the application program performs various operations by using the functions in those modules. Is going. “Loading” the hook processing module 400 means that the module 400 in which the hook procedure is mounted is incorporated in the process of the application program 122.

  When the hook processing module 400 is loaded, the function address of a specific drawing command issued from the application program 122 is the address of another function for executing a unique function implemented in the hook processing module 400. Is replaced. In the function of this unique function, processing for writing change information and image data into the RAM (described later) is executed, and then a normal GDI function is executed. When the hook processing module 400 is unloaded, the hook processing module 400 loaded in the process is unloaded after the function address replaced at the time of loading is restored.

  The hook processing module 400 can be loaded into the application program 122 and unloaded at any time as necessary. However, when the image transfer program 500a is activated, the hook processing module 400 is loaded into a specific application program 122 (presentation program in this embodiment) that is operating, and when the image transfer program 500a is terminated, the hook processing is performed. The image transfer program 500a is preferably configured to unload the module 400. In this way, since the hook processing module 400 can be operated only during the period in which the image transfer program 500a is being executed, a drawing command is executed when the image transfer program 500a is not executed (not activated) on the computer 100. To avoid undesired results. In this specification, the phrase “the image transfer program 500a is being executed on the computer 100” means that the process of the image transfer program 500a is activated.

  FIG. 14 is a flowchart showing the operations of the hook processing module 400 and the image transfer program 500a in the third embodiment. Steps S10 to S16 are executed by the hook processing module 400, and steps S20 to S26 are periodically executed by the image transfer program 500a.

  When a specific drawing command is issued from the application program 122, the hook processing module 400 hooks the drawing command in step S10 and acquires the drawing command instead of the GDI 124. Note that it is preferable that the drawing command hooked by the hook processing module 400 is not limited to all drawing commands, but only limited specific drawing commands. This is because there are many drawing commands issued by the application program 122. If all of them are hooked, there is a possibility that the processing speed may be lowered or the desired drawing may not be performed. Because.

  In step S12, a process of registering the change area information is executed according to the acquired drawing command. Specifically, the hook processing module 400 acquires the position and size of an area where drawing is performed according to the drawing command (change area Ra in FIG. 13B), and change area information 106a1 (hereinafter “ A process of directly writing the change area information A1 ”into the RAM 106 is executed.

  In step S14, the writing process of the image data of the change area Ra is executed. Specifically, the hook processing module 400 executes the process of expanding the image data in the change area Ra in accordance with the drawing command and directly writing the image data in the image data storage area 106b in the RAM 106.

  In step S16, the hook processing module 400 calls a normal GDI function according to the drawing command acquired in step S10, and executes the drawing process. Note that the display driver 126 and the projector driver 128 (FIG. 12) execute their respective processes according to the drawing command received from the GDI 124, in the same way as when the drawing command is directly passed to the GDI 124 without going through the hook processing module 400. . That is, the display driver 126 draws an image in the VRAM 114, and the projector driver 128 writes the change area information A2 indicating the drawing area in the RAM.

  On the other hand, in step S20, the capture module 510 determines an area of image data to be transferred to the projector 200 (referred to as a “screen update area”). FIG. 15 is a flowchart showing the detailed procedure of step S20. In steps S30 and S32, the first and second change area information A1 and A2 are acquired. As described above, the first change area information A1 is information representing an area drawn in the image data storage area 106b in the RAM 106 by the hook processing module 400, and is written in the RAM 106 by the hook processing module 400. It is. On the other hand, the second change area information A2 is information representing an area drawn in the VRAM 114 by the display driver 126, and is written in the RAM 106 by the projector driver 128.

  FIG. 16A shows an example of two change areas RA1 and RA2 represented by two change area information A1 and A2. Here, the two change areas RA1 and RA2 are arranged in the same screen area SCA. Here, the “screen area SCA” means the entire area of the image stored in the VRAM 114, which is equal to the entire area of the image data storage area 106b. Strictly speaking, the first change area RA1 is an area defined by an address in the image data storage area 106b, and the second change area RA2 is an area defined by an address in the VRAM 114. It can be expressed by the same screen area SCA.

  In the example of FIG. 16A, the two change regions RA1 and RA2 partially overlap, but the two change regions RA1 and RA2 may take various other relationships. For example, there are cases where the two change regions RA1 and RA2 do not overlap at all, and there are also cases where the two change regions RA1 and RA2 completely overlap. For example, when the hook processing module 400 performs drawing in accordance with a specific drawing command, and then the normal drawing modules 124, 126, and 128 perform drawing in the same region in accordance with the same drawing command, the two change regions RA1, RA2 Are the same. However, even when the same drawing command is executed, there may be a slight difference between the two change areas RA1 and RA2 depending on the setting of each module.

  FIG. 16B shows a region TG1 where the capture module 510 directly acquires an image from the RAM 106 during capture, and FIG. 16C shows a region TG2 where the image is acquired from the VRAM 114. These areas TG1 and TG2 are also referred to as “transfer areas”. As can be understood from this example, the image of the first change region RA1 (= TG1) is acquired directly from the RAM 106. On the other hand, the image of the area TG2 of the second change area RA2 that is not included in the first change area RA1 is acquired from the VRAM 114. The reason for this distinction is to reduce the number of images acquired from the VRAM 114 as much as possible and reduce the time required for the acquisition. For example, when the two change areas RA1 and RA2 are completely overlapped, it is not necessary to acquire an image from the VRAM 114, so that the transfer process can be performed at high speed. FIG. 16D shows the entire area (screen update area TTG) acquired by the capture module 510. This screen update area TTG corresponds to the sum area of the first and second change areas RA1 and RA2.

  The first change area information A1 may include a plurality of information corresponding to a plurality of drawing commands. In this case, the sum area of the drawing areas of the plurality of drawing commands becomes the first change area RA1. The same applies to the second change region RA2.

  In step S34 of FIG. 15, the capture module 510 calculates the difference between the change areas RA1 and RA2 represented by the two types of change area information A1 and A2. Specifically, a region TG2 (FIG. 16C) that is not included in the first change region RA1 in the second change region RA2 is calculated. In step S36, the capture module 510 executes an optimization process for the screen update area TTG (FIG. 16D).

  FIG. 17 is an explanatory diagram showing the contents of the screen update area optimization process. FIG. 17A shows the same screen update area TTG as in FIG. In the optimization process, as shown in FIG. 17B, the screen update area TTG is divided into adjacent rectangular areas R11 to R13 that do not overlap each other. And these rectangular area | regions R11-R13 are employ | adopted as a screen update area | region after optimization. Since each of the screen update areas R11 to R13 is rectangular, it is possible to reduce the amount of image data to be transferred compared to the case of transferring a rectangular image including the screen update area TTG before optimization. is there.

  In step S <b> 22 of FIG. 14, the capture module 510 acquires image data of an image portion corresponding to the screen update area. FIG. 18 is a flowchart showing the detailed procedure of step S22. In step S40, it is checked whether or not the second transfer area TG2 (FIG. 16C) is empty. When the second change area information A2 does not exist and when the second change area A2 is completely included in the first change area A1, the second transfer area TG2 is empty. If the second transfer area TG2 is empty, the process proceeds to step S44 described later. On the other hand, if the second transfer area TG2 is not empty, step S42 is executed. In step S42, the capture module 510 acquires the image data in the second transfer area TG2 from the VRAM 114 and writes it in the image data storage area 106b in the RAM 106. As a result, all the images in the screen update area TTG shown in FIG. 16D are stored in the image data storage area 106b. In step S44, the capture module 510 acquires the image data of the screen update area TTG from the image data storage area 106b of the RAM 106. Note that what is actually acquired is the image data of the individual screen update areas R11 to R13 (FIG. 10B) after the optimization processing.

  In step S <b> 24 of FIG. 14, the capture module 510 supplies the change area information and the image data to the data generation module 520. The data generation module 520 generates display data using the received data. In step S26, the display data thus generated is transferred to the projector 200a via the USB interface unit 112. When the screen update area is divided into a plurality of partial areas by the optimization process, display data is generated for each partial area. Each display data may be transferred together by one D9 command or may be transferred by separate D9 commands.

  On the other hand, the image development module 242 of the projector 200a (FIG. 9) controls the image processing unit 214 according to the received display data (header and image data), and updates the image displayed by the projector 200a.

  As described above, in the third embodiment, the hook processing module 400 hooks a specific drawing command in advance and executes a process of directly writing the image data of the change area in the RAM 106. As a result, the time required to transfer image data from the VRAM 114 to the RAM 106 can be saved. As a result, there is an advantage that the transfer speed when transferring image data to the projector 200a can be sufficiently increased.

  In a general personal computer, data transfer from the RAM 106 to the VRAM 114 can be executed at a very high speed, whereas data transfer from the VRAM 114 to the RAM 106 can be executed only several times slower than that. There are many. In the third embodiment, since the data transfer from the low-speed VRAM to the RAM can be reduced, the time required for transferring the image data to the projector 200 can be greatly reduced.

  In the third embodiment, the image portion of the area TG2 (FIG. 16C) not drawn by the hook processing module 400 is acquired from the VRAM 114 and transferred to the projector 200a. As a result, the images drawn by the normal drawing modules 124, 126, and 128 can be transferred to the projector 200 without omission.

D. Fourth embodiment:
FIG. 19 is an explanatory diagram showing the relationship between the change area and the screen update area in the fourth embodiment, and corresponds to FIG. 16 in the third embodiment. The fourth embodiment has the same apparatus configuration and overall processing flow as the third embodiment, but the area to be transferred is different from the third embodiment. Specifically, in the fourth embodiment, the first transfer region TG1 (FIG. 19B) in which an image is directly acquired from the RAM 106 is a portion where the first and second change regions RA1 and RA2 overlap. Set to In other words, the first transfer area TG1 is set to an area included in the first change area RA1 in the second change area RA2. On the other hand, the second transfer region TG2 (FIG. 19C) from which an image is acquired from the VRAM 114 is included in the first change region RA1 in the second change region RA2, as in the third embodiment. It is set to the part that is not. Accordingly, the screen update area TTG (FIG. 19D), which is the entire area to be transferred, is the same as the second change area RA2.

  Thus, in the fourth embodiment, the image in the second change area RA2, which is an area drawn in the VRAM 114 by the GDI 124 and the display driver 126, is transferred by the image transfer program 500a. The reason for performing the processing in this way is as follows. That is, since the drawing command hooked by the hook processing module 400 is again executed by the GDI 124 and the display driver 126, basically all drawing commands are executed by the GDI 124 and the display driver 126. Therefore, if the image of the second change area RA2 is transferred, it is possible to display a correct image on the projector 200a. However, if all the image data is acquired from the VRAM 114 at this time, there arises a problem that a considerable time is required for data transfer. Therefore, in the fourth embodiment, the time required for data acquisition is reduced by directly acquiring image data from the RAM 106 for the portion included in the first change area RA1 in the second change area RA2. doing. Further, the fourth embodiment is preferable to the first embodiment in that the amount of image data transferred is much smaller than that of the first embodiment.

  In many cases, the area drawn by the hook processing module 400 (first change area RA1) and the area drawn by the GDI 124 and the display driver 126 (second change area RA2) coincide with each other. Yes. Therefore, as in the fourth embodiment, even if image transfer of a portion of the first change area RA1 that is not included in the second change area RA2 is omitted, the image displayed on the projector 200a is uncomfortable. The possibility is negligible. On the other hand, in the third embodiment described above, since the image is transferred also in the first change area RA1 that does not overlap with the second change area RA2, the first and second change areas RA1 are assumed. , RA2 has the advantage of being able to transfer a more complete image even if it is significantly different.

  The image transfer program 500a includes a plurality of transfers including the transfer process of the third embodiment (also referred to as “first transfer mode”) and the transfer process of the fourth embodiment (also referred to as “second transfer mode”). It may be configured such that one of the modes can be selected and executed. The transfer mode may be selected by the user, or the image transfer program 500a automatically selects according to the processing capability (CPU processing speed, bus transfer speed, etc.) of the computer 100a (generally an image supply device). Alternatively, the transfer mode may be selected. In this way, it is possible to select a transfer mode that can transfer a preferable image at an appropriate transfer speed.

E. Example 5:
In the third and fourth embodiments described above, the projector 200a may be able to request image data of the entire screen from the computer 100a. FIG. 20 is a flowchart showing a procedure of processing in response to such a request.

  In the first step S500, the determination module 540 (FIG. 9) issues a request inquiry. This process is the same as step S310 in FIG.

  Since the OP code of the received SCSI command is “D9h” and the UD command code is “00h” (S504: Yes, S508: Yes), the dispatcher 226 (FIG. 9) of the projector 200a checks the status of the received data. Supply to module 250. If the UD command code is different from “00h”, processing corresponding to the UD command code is executed (for example, if the UD command code is “80h”, image display processing is executed). ). When the OP code is different from “D9h”, processing according to the OP code is executed (for example, access relay processing for the disk image 224 is executed).

  In response to receiving the request inquiry, the state check module 250 searches the RAM 206 (FIG. 2) for data to be transmitted to the computer 100a (S512). In the fifth embodiment, when the state check module 250 receives a full screen acquisition instruction from the user via the input unit 210 (FIG. 2), the command data representing the full screen transmission command is transmitted as data to be transmitted. The data is stored in the RAM 206 (FIG. 2). Such a full-screen acquisition instruction can be issued by the user when the display screen by the projector 200a is disturbed.

  When such command data is detected from the RAM 206, the state check module 250 transmits the detected command data to the computer 100a, and transmits a normal response to the computer 100a (S520, S524). On the other hand, when data to be transmitted is not detected, the status check module 250 transmits data indicating that there is no request to the computer 100a, and transmits a normal response to the computer 100a (S530, S534). . The processes in steps S520 and S530 are performed in the same manner as step S370 in FIG. 10, and the processes in steps S524 and S534 are performed in the same manner as in step S374 in FIG.

  The data received by the computer 100a is supplied to the determination module 540. When receiving the full screen transmission command (S540: Yes), the determination module 540 issues an instruction to transmit the image data of the full screen to the modules 510, 520, and 530 in the next step S550. . As a result, the image data of the full screen is transmitted to the projector 200a (S550), and the projector 200a displays the correct full screen (S554). On the other hand, when the full screen transmission command is not received (S540: No), the determination module 540 ends the process.

  The determination module 540 periodically executes a series of processes in steps S500 to S550 described above. Note that these series of processes are performed after the computer 100a receives a response to the completion of the display data transmission process (for example, S238 in FIG. 5) until transmission of the next display data is started (for example, FIG. 5 (S204).

  As described above, in the fifth embodiment, the image transfer program 500a transmits full-screen image data in response to a request from the projector 200a, so that the convenience for the user can be improved.

  The request transmitted from the projector 200a to the computer 100a is not limited to the image data transmission request for the entire screen, and any request can be adopted. For example, a request for changing the operation setting (for example, the transmission frequency of image data) of the image transfer program 500a may be employed. Here, the state check module 250 may issue a plurality of types of requests. In this case, information for identifying the request may be transmitted to the computer 100a. The determination module 540 may perform the requested process according to the request identification information. In general, the determination module 540 may perform the requested predetermined process in response to a request from the projector 200a. Here, when the data transmission by the projector 200a is possible, the request inquiry by the determination module 540 may be omitted. Further, the status check module 250 may automatically issue a request even when there is no user instruction. For example, the status check module 250 may periodically issue a full screen transmission request. The input unit 210 (FIG. 2) that receives user instructions is not limited to a device that includes operation buttons, and may be a device that receives instructions via a remote controller operated by the user.

F. Variations:
In addition, elements other than the elements claimed in the independent claims among the constituent elements in each of the above embodiments are additional elements and can be omitted as appropriate. The present invention is not limited to the above-described examples and embodiments, and can be implemented in various modes without departing from the gist thereof. For example, the following modifications are possible.

Modification 1:
In the above-described embodiments, the device types of the projectors 200 and 200a identified by the computers 100 and 100a are not limited to the “mass storage class”, and various types (classes) for general-purpose devices can be adopted. . In such a class for general-purpose devices, since the communication protocol is standardized, data communication between the image supply device and the image display device can be easily performed. Such a class of drivers is often widely used, and is often pre-installed in various devices having a USB interface. Therefore, data communication between the image supply device and the image display device can be performed without installing a dedicated driver. In addition, development of a dedicated driver can be omitted. As a result, it is possible to reduce labor for using the image display device.

  Here, it is preferable to adopt a class designed so that the data transfer speed from the computer 100, 100a to the projector 200, 200a does not become excessively slow. For example, any one selected from “Audio”, “Mass Storage”, and “Communication Device” can be adopted.

  The present invention can also be applied to future versions of USB. The interface is not limited to USB, and various general-purpose interfaces that can be arbitrarily connected to a plurality of types of general-purpose devices can be employed. In any case, it is preferable that the projectors 200 and 200a2 are identified as general-purpose devices. Here, the general-purpose device means a device that performs data communication using a standard interface protocol. As the standard protocol, a standardized protocol by the standard organization of the interface may be adopted, or a substantial standard in the industry may be adopted.

Modification 2:
In the above embodiments, the disk image 224 (FIGS. 3 and 9) may be omitted. In this case, what is necessary is just to acquire the program run with the computers 100 and 100a from the internet or another recording medium. However, if the data storage unit (for example, the disk image 224) accessible from the computers 100 and 100a is provided in the projectors 200 and 200a as in the above embodiments, various data stored in the data storage unit can be stored in the computer. 100, 100a. At this time, the communication command used for transmitting the display data is a predetermined command different from the command for reading the data in the data storage unit among the commands used in the communication protocol for the data storage device. Preferably there is. By so doing, it is possible to achieve both the transfer of display data and the reading of the data storage unit.

  Of the commands used in the communication protocol for the data storage device, either a command for reading data or a command issued by the image transfer program 500 (in particular, a display data transmission command). As the processing executed by the projectors 200 and 200a when a different command (for example, a WRITE command) is issued, any processing can be adopted. For example, the dispatcher 226 may send an error response to the computers 100 and 100a. Further, the dispatcher 226 may cause the data management module 230 to respond by supplying the received data to the SCSI driver 232.

  As data stored in advance in the storage area, arbitrary data such as instruction manuals of the projectors 200 and 200a can be employed. However, it is preferable to employ a program for causing the computers 100 and 100a to realize the function of transmitting image data (display data) to the projectors 200 and 200a as in the above embodiments. In this way, a program for transmitting image data can be easily provided to the computers 100 and 100a, so that the labor for using the projectors 200 and 200a can be reduced. Here, among programs (modules) used for transmission of image data, those arbitrarily selected can be adopted as those stored in the storage area. For example, modules that are normally incorporated in the computers 100 and 100a may be omitted. 9 and 12, when the projector driver 128 is incorporated in the computer 100a as a standard, the projector driver 128 of the disk image 224 may be omitted.

Modification 3:
In each of the embodiments described above, the method for capturing only the changed region is not limited to the method of the third embodiment shown in FIGS. 12 to 18 and the method of the fourth embodiment shown in FIG. Can be adopted. For example, the capture module 510 may detect the changed area by continuing to monitor the VRAM 114. In this case, the capture module 510 may acquire the image data of the changed area from the VRAM 114. Further, the optimization process as described in FIG. 17 may be omitted. In this case, the capture module 510 may capture a rectangular image that includes the screen update area TTG before optimization. Thus, the captured image may be larger than the changed area. However, it is preferable that the image is a partial image including a changed region in the entire screen.

  Further, as display data supplied from the computers 100, 100a to the projectors 200, 200a, various kinds of data other than those used in the above-described embodiments can be used. For example, display data that includes at least image data can be used. Specifically, for example, when transferring image data of the entire screen, there is no need to transfer a header (change area information).

  The display data preferably includes at least information indicating the position and size of the change area (screen update area) and image data in the change area. This is because the amount of data to be transferred is reduced if only the data relating to the change area (change area information and its image data) is transferred.

Modification 4:
In each of the above embodiments, the screen displayed by the projectors 200 and 200a is not limited to the screen displayed by the display device 118, and any screen can be adopted. For example, only images drawn by a specific application operating on the computers 100 and 100a may be displayed on the projectors 200 and 200a. In this case, the capture module 510 may capture an image drawn by the application.

Modification 5:
In each of the above embodiments, a SCSI command set is used. Accordingly, even when various data (for example, the status data in FIG. 10: S370 and the command data in FIG. 20: S520) are transmitted from the projectors 200, 200a to the computers 100, 100a, the data size is the same as that of the SCSI. It is determined by the computers 100 and 100a corresponding to the initiator (in the above embodiments, it is set to a predetermined size). Here, when the size of data to be transmitted is large, a part of the data may remain in the projectors 200 and 200a. In such a case, the size of the remaining data is written in the data transferred to the computers 100 and 100a, and the computers 100 and 100a transmit the data to the projectors 200 and 200a until all the remaining data is received. What is necessary is just to repeatedly perform the process to make.

Modification 6:
The communication procedure for transferring display data, status data, and command data is not limited to the procedure in each of the above embodiments, and various procedures can be employed. For example, in step S26 of FIG. 14, the display data may be divided and transmitted as in the example of FIG. In each of the above embodiments, the SCSI command set is used for data communication. However, any command set used for data communication can be used. Further, as a data communication procedure, a procedure suitable for the adopted command set may be adopted.

Modification 7:
In the above embodiment, the image portion of the second transfer area TG2 (FIG. 16C, FIG. 19C) is acquired from the VRAM 114 and once written in the image data storage area 106b in the RAM 106, then the RAM 106 The image of the screen update area TTG is acquired from the image data and transferred via the interface. However, the process of writing in the image data storage area 106b can be omitted. However, according to the procedure of the above embodiment, when the image is finally transferred through the interface, the image can be acquired from one image data storage area 106b, so that there is an advantage that the processing is simplified.

Modification 8:
In the above embodiment, the drawing module is divided into three modules, the GDI 124, the display driver 126, and the projector driver 128. However, the modules can be arbitrarily classified, and these functions can be combined into one module. It is also possible to combine the functions of the display driver 126 and the projector driver 128 into one module.

Modification 9:
In the above embodiment, a personal computer is used as the image supply device, but other types of computers (mobile computer, handheld computer, workstation, etc.) may be used instead. In addition to these computers, an apparatus having an interface and a function similar to that of a computer may be used. Such devices include, for example, information mobile terminals, mobile phones, mail terminals, game machines, set top boxes, and the like. As the image display device, various display devices other than the projector can be used.

Modification 10:
In the above embodiment, a part of the functions realized by software may be realized by hardware, or a part of the functions realized by hardware may be realized by software.

DESCRIPTION OF SYMBOLS 10 ... Image display system 60 ... Display screen 70 ... Projection display screen 100, 100a ... Personal computer (PC)
102 ... CPU
104 ... ROM
106 ... RAM
106a ... Change area information 106a1 ... Change area information 106a2 ... Change area information 106b ... Image data storage area 108 ... Hard disk drive 110 ... Input section 112 ... USB interface section 114. ..VRAM
116 ... Graphic controller 118 ... Display device 120 ... Bus 122 ... Application program 124 ... GDI (graphics device interface)
126 ... Display driver 128 ... Projector driver 130 ... File system module 132 ... SCSI driver 134 ... Mass storage driver 136 ... USB module 200, 200a ... Projector 202 ... CPU
204 ... ROM
206 ... RAM
210 ... Input unit 212 ... USB interface unit 214 ... Image processing unit 216 ... Projection unit 218 ... Bus 224 ... Disk image 226 ... Command dispatcher module 230 ... Data management Module 232 ... SCSI driver 234 ... Mass storage driver 236 ... USB module 240 ... Image display module 242 ... Image development module 244 ... Data acquisition module 250 ... Status check module 300. USB cable 400 ... Hook processing module 500, 500a ... Image transfer program 510 ... Capture module 520 ... Data generation module 530 ... SCSI wrapper module 540 ... Judgment module

Claims (16)

The interface of the image supply apparatus is connected to a general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices, and images are sequentially displayed based on a plurality of image data sequentially supplied from the image supply apparatus. An image display device,
A communication control unit for controlling data communication via the interface;
An image display unit for displaying an image based on the image data;
With
The communication control unit transmits, to the image supply apparatus, identification information indicating a specific general-purpose device that is not an image display device, as identification information indicating a device type of the image display apparatus, for the start of the data communication.
The communication control unit receives the image data from the image supply device as the general-purpose device and supplies the received image data to the image display unit for display.
Image display device. The image display device according to claim 1,
The interface is a USB interface;
The identification information is set in the mass storage class,
Image display device. The image display device according to claim 2, further comprising:
A data storage unit accessible by the image supply device;
The communication control unit
(I) A communication command used in communication by the mass storage class, and when receiving a communication command for data read, supply the received data to the data storage unit,
(Ii) When a predetermined communication command different from the communication command for data read is received, the received data is supplied to the image display unit as image data.
Image display device. The image display device according to claim 3,
The data storage unit stores an image transfer program for causing a computer to realize a function of transmitting the image data to the image display device using communication by the mass storage class.
Image display device. The image display device according to claim 4,
The image transfer program is configured to display the changed image in the current image in order to cause the image display device to display an image in which only a part of the current image to be displayed is changed by the transmitted image data. Causing the computer to realize a function of transmitting updated image data representing only a partial area including the area;
Image display device. An image display device according to any one of claims 1 to 4,
The image display unit updates only the partial area when receiving updated image data representing only a partial area of the current image to be displayed by the received image data.
Image display device. The interface of the image supply apparatus is connected to a general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices, and images are sequentially displayed based on a plurality of image data sequentially supplied from the image supply apparatus. A control method for an image display device, comprising:
The image display device includes an image display unit that displays an image based on the image data,
The control method is:
(A) When the image display apparatus starts the data communication, identification information indicating a specific general-purpose device that is not an image display device is transmitted to the image supply apparatus as identification information indicating a device type of the image display apparatus. Sending, and
(B) the image display device receiving the image data from the image supply device as the general-purpose device and supplying the received image data to the image display unit for display;
A control method comprising: The interface of the image supply apparatus is connected to a general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices, and images are sequentially displayed based on a plurality of image data sequentially supplied from the image supply apparatus. A computer program for causing a computer to execute processing for controlling an image display device,
The image display device includes an image display unit that displays an image based on the image data,
The computer program is
(A) a function of transmitting identification information indicating a specific general-purpose device that is not an image display device to the image supply device as identification information indicating a device type of the image display device for the start of the data communication;
(B) a function of receiving the image data from the image supply device as the general-purpose device and supplying the received image data to the image display unit for display;
A computer program that causes a computer to realize An image supply device for sequentially supplying a plurality of image data to an image display device that receives image data as a specific general-purpose device that is not an image display device, and displaying the images sequentially,
A general-purpose interface that is connected to the image display device and can be arbitrarily connected to a plurality of types of general-purpose devices; and
A communication control unit that controls data communication via the interface by identifying a device type of the image display device as the general-purpose device;
An image transfer processing module for controlling the communication control unit to transmit the image data for display to the image display device identified as the general-purpose device that is not an image display device;
Comprising
Image supply device. The image supply device according to claim 9,
The interface is a USB interface;
The communication control unit identifies a device type of the image display device as a mass storage class;
Image supply device. The image supply device according to claim 10,
The image display device further includes a data storage unit accessible by the image supply device,
The image supply device further includes:
A communication command used in communication by the mass storage class, comprising a data read module that reads data stored in the data storage unit by using a communication command for data read,
The image transfer processing module transmits the image data by using a predetermined communication command different from a communication command for data reading.
Image supply device. An image supply device according to any one of claims 9 to 11,
The image transfer processing module is configured to display the change in the current image in order to cause the image display device to display an image in which only a part of the current image to be displayed is changed according to the transmitted image data. A function of transmitting updated image data representing only a part of the area including the area
Image supply device. The image supply device according to claim 12, further comprising:
An application program capable of issuing image drawing commands;
A drawing module for processing a drawing command issued by the application program;
A hook processing module that hooks a specific drawing command issued by the application program in advance and draws an image in a specific transfer image storage area in the general-purpose memory according to the acquired drawing command;
With
The image transfer processing module has a function of acquiring an image from the transfer image storage area and transferring the acquired image to the image display device via the interface. The hook processing module includes the transfer image. A function of writing first change area information indicating a first change area, which is an area in which an image is drawn in accordance with the specific drawing command, in the storage area, and the specific drawing command; A function of supplying the drawing command to the drawing module after processing;
The drawing module has a function of drawing an image in a frame memory in accordance with a drawing command received from the application program or the hook processing module, and an area in the frame memory in which an image is drawn according to the drawing command. Having a function of writing second change area information indicating a second change area in the general-purpose memory;
The image transfer processing module
(I) Referring to the first and second change area information stored in the general-purpose memory, the second change area corresponds to an area not included in the first change area. Obtaining an image portion from the frame memory;
(Ii) obtaining an image portion corresponding to the first change area from the transfer image storage area without obtaining from the frame memory;
(Iii) The acquired image portion is transferred to the image display device via the interface together with screen update area information indicating a screen update area that is a sum of the first and second change areas. Feeding device. The image supply device according to claim 12, further comprising:
An application program capable of issuing image drawing commands;
A drawing module for processing a drawing command issued by the application program;
A hook processing module that hooks a specific drawing command issued by the application program in advance and draws an image in a specific transfer image storage area in the general-purpose memory according to the acquired drawing command;
With
The image transfer processing module has a function of acquiring an image from the transfer image storage area and transferring the acquired image to the image display device via the interface. The hook processing module includes the transfer image. A function of writing first change area information indicating a first change area, which is an area in which an image is drawn in accordance with the specific drawing command, in the storage area, and the specific drawing command; A function of supplying the drawing command to the drawing module after processing;
The drawing module has a function of drawing an image in a frame memory in accordance with a drawing command received from the application program or the hook processing module, and an area in the frame memory in which an image is drawn according to the drawing command. Having a function of writing second change area information indicating a second change area in the general-purpose memory;
The image transfer processing module
(I) Referring to the first and second change area information stored in the general-purpose memory, the second change area corresponds to an area not included in the first change area. Obtaining an image portion from the frame memory;
(Ii) An image portion corresponding to an area included in the first change area among the second change areas is acquired from the transfer image storage area without acquiring from the frame memory;
(Iii) The image supply device, wherein the acquired image portion is transferred to the image display device via the interface together with screen update region information indicating a screen update region that is the same as the second change region. An image display apparatus that is connected to a general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices and that receives image data as a specific general-purpose device that is not an image display device. A method of supplying image data and displaying images sequentially,
(A) controlling the data communication via the interface by identifying the device type of the image display device as the general-purpose device;
(B) The image supply device transmits the image data for display to the image display device identified as the general-purpose device that is not an image display device via the interface;
A display method comprising: An image display apparatus that is connected to a general-purpose interface that can be arbitrarily connected to a plurality of types of general-purpose devices and that receives image data as a specific general-purpose device that is not an image display device. A computer program for supplying image data and causing a computer to execute processing for sequentially displaying images,
(A) a function of controlling data communication via the interface by identifying a device type of the image display device as the general-purpose device;
(B) a function of transmitting the image data for display to the image display device identified as the general-purpose device that is not an image display device via the interface;
A computer program that causes a computer to realize

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