JP2009171021A - Display image synchronization program, digital camera, and display image synchronization system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To synchronize display contents onto a monitor among a plurality of cameras. <P>SOLUTION: A transmission side camera 200 reads display images recorded in a memory card 204, outputs and displays the display image and a pointer for indicating an optional position within the display image on an LCD panel 205, and transmits the data of the display image output onto the LCD panel 205 and data relating to the display position of the pointer within the display image as synchronization data to the reception side apparatus of a communicating party. When receiving the synchronization data, a reception side camera 300 outputs image data included in the synchronization data to the LCD panel 205 to display the display image, specifies the display position of the pointer within the display image on the basis of pointer data included in the synchronization data, and displays the pointer at the specified position. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention includes a display image synchronization program for synchronizing display contents of a display device between a transmission side device and a reception side device, a digital camera that executes the display image synchronization program, and a plurality of digital cameras. The present invention relates to a display image synchronization system.

  The following image transfer system between digital cameras is known. When there are a plurality of digital cameras with a communication function, images can be easily exchanged between a plurality of people by transmitting and receiving images acquired between the digital cameras (for example, Patent Document 1). .

JP 2004-228966 A

  However, since the conventional image transfer system is intended for exchanging images between a plurality of users, when a plurality of people try to view the same image at the same time using this image transfer system, Couldn't enjoy talking while paying attention to the same part in the image.

The present invention displays an original image recorded on a recording medium and a display device generated based on the original image on a display device included in each device between the transmitting device and the receiving device. In order to synchronize the display image to be transmitted, the transmission-side device outputs a display image and a pointer for pointing an arbitrary position in the display image to a display device (transmission-side display device) provided in the transmission-side device. The display image data (image data) output on the display device on the transmission side and the data on the display position of the pointer in the display image (pointer data) are transmitted to the receiving device of the communication partner. To do. The receiving device receives the image data and pointer data transmitted from the transmitting device of the communication partner, and outputs the received image data to a display device (receiving device) provided in the receiving device for display. An image is displayed, the display position of the pointer in the display image is specified based on the received pointer data, and the pointer is displayed at the specified position.
In the present invention, the transmission side device moves the pointer in the display image based on an instruction from the user of the transmission side device, and transmits the movement information of the pointer to the reception side device of the communication partner. It is preferable that the device moves the pointer in the display image based on the received pointer movement information.
The transmission side device may transmit either the coordinate value after the pointer movement or the movement direction and the movement amount of the pointer as movement information of the pointer to the reception side device of the communication partner.
The shape of the pointer in the receiving device is set in advance, and the receiving device may draw a pointer having a preset shape at the display position of the pointer in the specified display image.
The transmitting device deletes the pointer displayed in the display image based on an instruction from the user of the transmitting device, and deletes information for instructing deletion of the pointer to the receiving device of the communication partner. The transmission side device may delete the pointer displayed in the display image based on the received pointer deletion information.
When the pointer is deleted, the transmitting device may display the pointer again at the display position at the time of deletion after a predetermined time has elapsed.
When the pointer is redisplayed, the transmitting device transmits redisplay information for instructing redisplay to the receiving device of the communication partner, and on the receiving device, based on the received pointer redisplay information, You may make it display a pointer again in the display position at the time of deletion.
The receiving device may delete the pointer displayed in the display image based on an instruction from the user of the receiving device.
The transmission-side device performs resolution conversion on the display image displayed on the transmission-side display device, enlarges or reduces the display image, and transmits zoom information about the enlargement or reduction magnification of the display image to the communication partner. The image may be transmitted to the reception side device, and the reception side device may enlarge or reduce the display image displayed on the reception side display device based on the received zoom information of the display image.
The transmission-side device has a first zoom mode for enlarging or reducing the image around the display position of the pointer in the display image, and an image centered on the center position of the range displayed on the transmission-side display device of the display image. One of the second zoom modes for enlarging or reducing the image may be selected to enlarge or reduce the display image.
The receiving device may perform resolution conversion on the display image displayed on the receiving display device to enlarge or reduce the image.
The receiving-side device performs first zoom processing for enlarging or reducing the image around the display position of the pointer in the display image, and an image centered on the center position of the range displayed on the display-side display device for the display image. The display image may be enlarged or reduced by any one of the second zoom processes for enlarging or reducing the image.
In the recording medium of the transmission side device, the transmission side device displays an enlarged display in which the display image after enlargement and the image display range are equivalent from the original image when the enlargement magnification of the display image exceeds a predetermined magnification. Cut out the image, display the enlarged display image on the transmission side display device, and transmit the image data of the enlarged display image to the receiving side device of the communication partner. The image data may be output and displayed on the receiving display device.
Based on an instruction from the user of the transmission side device, the transmission side device scrolls the display image displayed on the transmission side display device, and transmits scroll information regarding the scrolling of the display image to the reception side device of the communication partner. Then, the receiving device may scroll the display image displayed on the receiving display device based on the received scroll information.
When the pointer is moved in the direction outside the screen of the transmission-side display device, the transmission-side device scrolls the display image in the movement direction, and scroll information regarding the scrolling of the display image is displayed on the reception side of the communication partner. The image to be transmitted to the device and the receiving device may scroll the display image displayed on the receiving display device based on the received scroll information.
Based on an instruction from the user of the receiving device, the receiving device further executes a receiving scroll procedure for scrolling the display image displayed on the transmitting display device, and receives the scroll information from the transmitting device. In this case, the scroll result based on the scroll procedure on the receiving side may be discarded and scrolling based on the scroll information may be performed.
The transmitting device displays a plurality of display images selected by the user of the transmitting device among the display images recorded on the recording medium in order at a predetermined time interval on the transmitting display device to display a slide show. The image data of the plurality of display images selected by the user of the transmission-side device is transmitted to the reception-side device of the communication partner at a predetermined time interval and in order, and the reception-side device receives the plurality of display-image images. Each time data is received, a slide show may be executed by switching to the display device on the receiving side.
The transmission side device stops the slide show being executed on the transmission side display device when the user of the transmission side device instructs to stop the slide show, and the reception side device stops the image data of a plurality of display images. The slide show that is being executed on the display device on the receiving side may be stopped in response to the stop of reception.
Based on the received image data, the receiving side device selects a display image designated by the user from among the display images, and transmits the original image corresponding to the selected display image to the receiving side device. You may make it transmit the original image request information which requests | requires transmission to a receiving side apparatus.
The transmitting device may receive the original image request information and transmit the requested original image to the receiving device based on the received original image request information.
The transmission-side device may reproduce audio data or music data when displaying the display-use image on the transmission-side image display device, and the reception-side device displays the display-use image on the reception-side image display device. Sometimes audio data or music data may be reproduced.

  According to the present invention, a plurality of users can view an image while paying attention to the same part in the image.

  FIG. 1 is a block diagram showing a configuration of an embodiment of a display image synchronization system according to the present embodiment. The display image synchronization system 100 includes one digital camera (transmission-side camera) 200 that operates as a transmission-side device and at least one digital camera (reception in the example shown in FIG. 1) that operates as a reception-side device. Side camera) 300 is wirelessly connected.

  In this display image synchronization system 100, by synchronizing the contents displayed on the monitors included in each of the transmission side camera 200 and the reception side camera 300, the users possessing the respective cameras are simultaneously the same. Enable viewing of images. That is, when an image recorded on the sending camera 200 is displayed on a monitor provided on the sender camera 200, the screen size of the monitor is limited, so that the displayed image can be viewed simultaneously by a plurality of people. Difficult to do. For this reason, in this embodiment, an image to be displayed is transmitted from the transmission-side camera 200 to the reception-side camera 300 by wireless communication, and the same image is also displayed on a monitor included in the reception-side camera 300.

  At this time, if the number of receiving cameras 300 is increased in accordance with the number of viewers, the same image can be displayed on a plurality of monitors, so that a plurality of people can view the same image at the same time. Is possible. Further, in the present embodiment, a pointer for indicating where the user who is watching the monitor of the transmitting camera 200 is paying attention can be displayed superimposed on the image, and information on the position of the pointer is displayed. Are also transmitted to the receiving camera 300. The receiving camera 300 displays a pointer at the same position as the pointer position in the transmitting camera 200 based on the received information regarding the position of the pointer.

  That is, the position of the pointer displayed on the image is also synchronized between the transmission side camera 200 and the reception side camera 300. Thereby, the person who is watching the monitor of the transmitting camera 200 and the person who is watching the monitor of the receiving camera 300 can view the image while paying attention to the same position of the image.

  FIG. 2 is a diagram schematically illustrating a configuration example of the display image synchronization system 100 in the case where there is one receiver camera 300. In FIG. 2, as shown in FIG. 2A, both the transmission-side camera 200 and the reception-side camera 300 are provided with an infrared port 2 a for performing wireless communication, for example, infrared communication, on the front part of the camera. Further, as shown in FIG. 2B, a monitor for displaying an image on the back surface of the camera, for example, a liquid crystal monitor 2b is provided. Various operation switches such as a cross switch 2e, a determination switch 2f, and zoom switches 2g and 2h are arranged on the rear surface of the camera. As shown in FIG. 2B, the same image is displayed on each monitor 2b of the transmission side camera 200 and the reception side camera, and the position of the pointer 2c on the image is also synchronized.

  FIG. 3 is a block diagram showing the configuration of an embodiment of the digital camera in this embodiment, that is, the transmission-side camera 200 and the reception-side camera 300. Assume that the transmission-side camera 200 and the reception-side camera 300 in this embodiment have the same configuration, and here, the transmission-side camera 200 and the reception-side camera 300 will be described together. In the following description, the transmitting camera 200 and the receiving camera 300 are collectively referred to as a “digital camera”.

  In the example illustrated in FIG. 3, the digital camera uses an infrared ray as a communication medium. The infrared camera can be used to remotely control the receiving camera 300 from the transmitting camera 200. The use of infrared rays as a communication medium in this way is advantageous in that the communication speed is fast and the power consumption is low. In addition, although the infrared communication has a short communication distance, considering the use form in this embodiment in which a plurality of people browse images while synchronizing between the transmitting camera 200 and the receiving camera 300, the communication distance is It doesn't matter if it is short.

  In the example illustrated in FIG. 3, the digital camera includes a DSC engine 201 that controls most of the functions of the digital camera. Inside the DSC engine 201, a main CPU 201a, an image processing circuit 201b, a JPEG codec 201c, and a display controller are included. 201d, Audio codec 201e, and SIO or GPIO 201f are provided. In addition, a timer, an interrupt controller, an AD converter, a USB controller, and the like (not shown) are also provided in the DSC engine 201.

  An SDRAM 202, a flash memory 203, a memory card 204, an LCD panel 205, a crystal oscillator (X'tal) 206, a speaker 207, and an operation switch 208 are connected to the DSC engine 201 as external devices. Further, an imaging circuit including a photographing lens 209, an imaging element (CCD) 210, an AFE 211, a TG (timing generator) not shown, and the like are also connected.

  The digital camera further includes a sub CPU 212, a power switch 213, an Ir module 214 for infrared communication, and a power circuit 215. The sub CPU 212 controls the start (power ON) and stop (power OFF) of the digital camera based on the operation of the power switch 213 by the user. The serial communication port of the Ir module 214 for infrared communication is connected to both the DSC engine 201 and the sub CPU 212. In addition, the power supply circuit 215 supplies power of various voltages necessary for the operation of the digital camera to each unit. If the battery 215a is inserted in the digital camera, the power is always supplied from the power supply circuit 215 to the sub CPU and continues to operate. Although not shown, a backup battery is also provided in addition to the main battery (battery 215a), and only the calendar function of the sub CPU 212 continues to work even when there is no main battery.

  As described above, the digital camera in this embodiment has a remote control function by infrared communication, and can accept activation from another camera or a remote controller. For example, when the receiving camera 300 is turned off, the receiving camera 300 can be turned on by remote control from the sending camera 200. Therefore, the digital camera stands by in a state where the sub CPU 212 controls the power supply circuit 215 to supply power only to the Ir module 214 even when the power is turned off.

  As described above, the Ir module 214 has two serial communication ports: a port connected to the DSC engine 201 (DSC engine side communication port) and a port connected to the sub CPU 212 (sub CPU side communication port). One is provided. In the standby state when the power is turned off, the serial communication port of the Ir module 214 is active only on the communication port on the sub CPU side, and the communication port on the DSC engine side is in the Hi-Z state. Since no power is supplied to the DSC engine 201 in the standby state, the chip is protected in this way.

  In order to reduce the power consumption of the Ir module 214 in the standby state as much as possible, the Ir module 214 may have a simple configuration including only the transmission side LED 214a and its driver, and the reception side Photo diode 214b and its receiver. preferable.

  When the sub CPU 212 detects that the remote control communication from another camera has been received while the digital camera is in the standby state, the sub CPU 212 activates the camera. That is, the camera is turned on. Further, the sub CPU 212 constantly monitors pressing of the power switch 213, and activates the camera even when it is pressed. As a result, power is supplied from the power supply circuit 215 to the DSC engine 201. When power is supplied to the DSC engine 201 in this way, the sub CPU 212 closes the communication port on the sub CPU side of the Ir module 214 and sets the communication port on the DSC engine side to Active.

  In the example illustrated in FIG. 3, only the power switch 213 is connected to the sub CPU 212 as a switch for the user to turn on the camera. However, in order to enable the power to be turned on even when the playback switch is operated by the user, or to turn on the power even when the camera is connected to a special interface (cradle or the like), the sub CPU 212 Are connected so that a signal from a regeneration switch, a cradle or the like is input.

  The operation switch 208 that is not related to the activation of the camera is connected to the DSC engine 201 side. Since the operation switch 208 is directly monitored by the main CPU 201a of the DSC engine 201 while the camera is turned on, a response is given. Can be fast.

  The SDRAM 202 is used as both an image memory and a work memory of the main CPU 201a. Since the access frequency is very high, a high-speed memory device such as a DDR-SDRAM is used. The flash memory 203 stores a program (firmware) executed by the main CPU 201a, camera-specific adjustment values, camera setting information by a user, a file of captured image data, and the like. The memory card 204 is a detachable recording medium, and when a storage area is available, a captured image is recorded here. The LCD panel 205 is a display device with a built-in camera, and displays various information such as menus in addition to images.

  Hereinafter, general operations of the digital camera shown in FIG. 3 will be described. In this digital camera, the subject image is formed on the CCD 210 by the photographing lens 209. During shooting, a mechanical shutter, a mechanical aperture, a focus lens, a ZOOM lens, and the like (not shown) are driven to perform shooting. A motor driver IC (not shown) is used for these driving operations, and the control is performed by the SIO (serial port) or GPIO 201f (parallel port) of the DSC engine 201. The CCD 210 is driven by a TG (not shown), whereby the subject is exposed and the image signal is read out. Control of this TG and AFE 211 described later is performed by serial communication using the SIO 201 f of the DSC engine 201.

  The image signal read from the CCD 210 is sampled by the AFE 211 and converted into digital data for each pixel. This digital image data (RAW data) is input to the DSC engine 201 and processed by the internal image processing circuit 201b. In this image processing circuit 201b, various processes such as defective pixel correction, OB clamping, WB adjustment, γ correction, color interpolation, color conversion (color correction), resolution conversion, and edge enhancement are performed, and the image data becomes YCbCr data. And stored in the SDRAM 202.

  At the time of shooting, the main CPU 201a sets the camera mode to the view mode, and the display controller 201d starts displaying a through image on the LCD panel 205. Specifically, the image processing by the image processing circuit 201b described above is divided into pre-processing mainly for correction of image data and post-processing mainly for processing relating to the color of the image. The processing and post-processing are performed together to create YCbCr data of a through image. The YCbCr data of the through image is stored in the SDRAM 202, and the display controller 201d reads the YCbCr data of the through image from the SDRAM 202 and outputs it to the LCD panel 205.

  At the same time, the main CPU 201a starts AE / AF / AWB control. Specifically, the AE / AF / AWB evaluation values are extracted together with the creation of the YCbCr data of the through image, and these evaluation values are processed to control the AE / AF / AWB.

  When the composition of the subject is determined in the View mode, and when focusing and AE calculation are completed, the camera mode is switched to the still image shooting mode by the user fully pressing the release button, and still image shooting is started. To do. That is, in this still image shooting mode, the subject is exposed for the shutter time determined by the above-described AE calculation, and then the image signal of the still image shot with the mechanical shutter closed is read.

  In the still image shooting mode, since the RAW data is read out by multi-field of interlace scanning, the process after the color interpolation in the post-process described above cannot be executed. In addition, since the AWB calculation processing of the captured still image has not yet been performed, WB adjustment (AWB adjustment) cannot be performed. For this reason, in the still image shooting mode, the image processing circuit 201 b first performs pre-processing before the WB adjustment on the image data, and stores the pre-processed image data in the SDRAM 202.

  When all the fields of the RAW data have been read, the image processing circuit 201b reads the preprocessed image data stored in the SDRAM 202, and performs post-processing on the read data. In that case, WB adjustment (AWB adjustment) is performed based on the above-described AWB calculation processing. The post-processed still image data is stored in the SDRAM 202 as high resolution YCbCr data.

  In this still image shooting mode, the image processing circuit 201b also creates YCbCr data (thumbnail data) of a thumbnail image based on the image data and stores it in the SDRAM 202. The still image data and the thumbnail data are compressed by the JPEG codec 201c and recorded on the memory card 204 as a JPEG file such as an Exif (Exchangeable Image File Format for Digital Still Camera).

  That is, the JPEG file includes thumbnail image data (160 × 120 pixels resolution) that is a list display image, and still image data that is an original image with a higher resolution than the thumbnail image, which is the source of the thumbnail image. include. However, since the thumbnail image has a coarser resolution than the display resolution of the LCD panel 205, in the present embodiment, a display image matching the display resolution of the LCD panel 205 is generated from the still image data. The resolution of the display image is, for example, VGA (640 × 480 pixels). The display image may be generated from still image data each time it is used, or may be added to a JPEG file and recorded. At this time, if the memory card 204 is not inserted or there is no free space, the JPEG file is recorded in the flash memory 203. Thereafter, the camera returns to the View mode again to prepare for the next shooting.

  The captured image can be read out from the memory card 204 or the flash memory 203 and reproduced. The user can switch the camera mode to the playback mode by pressing a playback switch included in the operation switch 208. In the playback mode, the main CPU 201a reads a JPEG file from the memory card 204 or the flash memory 203, and the JPEG codec 201c decompresses the read JPEG file.

  The JPEG codec 201c temporarily stores the decompressed image data in the SDRAM 202, and the image processing circuit 201b reads the read image data, performs resolution conversion in accordance with the display resolution of the LCD panel 205, and converts the display image obtained by the resolution conversion. The YCbCr data is stored in the SDRAM 202. The display controller 201 d reads the YCbCr data stored in the SDRAM 202 and displays it on the LCD panel 205.

  The user can play back the images recorded in the memory card 204 and the flash memory 203 in order by operating the operation switch 208 to frame-forward the images displayed on the LCD panel 205. Further, when an audio file or a music file is recorded in the memory card 204 or the flash memory 203, it is possible to reproduce the audio and music together with the image. In this case, the audio codec 201e reads out and reproduces an audio file or a music file from the memory card 204 or the flash memory 203, and outputs it from the speaker 207.

  Next, referring to FIG. 4, when the above-described digital camera is used as the transmission-side camera 200 and the reception-side camera 300, display contents are synchronized between the transmission-side camera 200 and the reception-side camera 300. Processing will be described. In FIG. 4, the process shown in FIG. 4A is a process executed by the transmission-side camera 200, and the process shown in FIG. 4B is a process executed by the reception-side camera 300.

  With the processing shown in FIG. 4, a command or data is transmitted from the transmission side camera 200 to the reception side camera 300, and the reception side camera 300 performs processing based on the received command or data. And the content displayed on the LCD panel 205 of the receiving camera 300 can be synchronized. In FIG. 4, arrows indicating data exchange are shown between the steps of the process shown in FIG. 4A and the steps of the process shown in FIG.

  First, in the transmission-side camera 200, when the playback mode described above is selected by the user, the process shown in FIG. That is, the process shown in FIG. 4A is executed by the DSC engine 201 included in the transmission-side camera 200 as a program that is activated when the user selects the above-described playback mode.

  In step S1, an image to be transmitted to the receiving camera 300 is selected as a transmission target image based on an instruction from the user. For example, the display controller 201 d reads thumbnail images from a JPEG file stored in the memory card 204 or the flash memory 203 and displays a list on the LCD monitor 205. Then, the user selects an image desired to be transmitted to the receiving camera 300 from among the thumbnail images displayed in a list, that is, an image desired to be viewed simultaneously by a large number of people. The main CPU 201a selects an image selected by the user as a transmission target image.

  For example, the display controller 201d displays a list of thumbnail images on the LCD monitor 205 as shown in FIG. The image selection status is represented by a cursor frame 5a, and the user can move the cursor frame 5a with the cross switch 2e shown in FIG. The user can select an image by pressing the determination switch 2f shown in FIG. 2 in a state where the cursor frame 5a is aligned with any thumbnail image.

  When a transmission target image is selected by the user, the main CPU 201a stores an image ID corresponding to the image in the SDRAM 202. When a plurality of images are selected by the user in the above-described procedure, a list of IDs corresponding to the respective images, that is, an image ID list including a plurality of image IDs is stored in the SDRAM 202. This image ID list can be recorded and saved in the memory card 204 or the flash memory 203 for later reference. When the selected image is deleted after selection in the transmitting camera 200, it is desirable to delete the image ID corresponding to the deleted image stored in the memory card 204 or the flash memory 203.

  In step S2, it is determined whether or not the selection of the transmission target image by the user has been completed. If it is determined that the user has completed, the process proceeds to step S3. In step S3, using the remote control function described above, an activation command is issued to the receiving camera 300 so as to turn on the power of the receiving camera 300 by infrared remote control communication using the Ir module 214. If the receiving camera 300 does not support power-on by remote control, it is necessary to request the person who has the receiving camera 300 to turn on the power.

  In the receiving camera 300, when the activation command is received from the transmitting camera 200 in step S13, the sub CPU 212 turns on the power of the receiving camera 300 as described above. When the receiving camera 300 is activated, the main CPU 201a of the receiving camera 300 returns a response for notifying the transmitting camera 200 that the camera has been activated.

  In the transmission-side camera 200, when the main CPU 201a detects that there is a response from the reception-side camera 300, the main CPU 201a performs remote control communication, sets the communication mode for the reception-side camera 200, and the current remote control communication. A command is issued to switch from the mode for performing communication to an image communication mode in which communication can be performed at higher speed, and the transmission-side camera 200 itself also switches the communication mode to the image communication mode. In the receiving camera 300, when the main CPU 201a receives a communication mode switching command, the main CPU 201a switches to the image communication mode.

  After this, both cameras communicate using the image communication mode. When the main CPU 201a of the transmission side camera 200 is switched to the image communication mode, the main CPU 201a inquires about the resolution (the number of effective lines and the aspect ratio) of the LCD panel 205 of the reception side camera 300. Before transmitting an image to the camera 300, it may be converted into an image of an optimal size based on the inquiry result. Of course, the receiving camera 300 can accurately display an image of any size on its own LCD panel 205. However, if the resolution of the LCD panel 205 of the receiving camera 300 is known, there is an advantage that the transmitting camera does not need to send an image larger than necessary and the time required for transmission can be shortened.

  In step S4, the transmission target image selected in the above-described processing is transmitted from the transmission side camera 200 to the reception side camera. In addition, the display controller 201 d of the transmission-side camera 200 displays a transmission target image on the LCD panel 205. Here, the main CPU 201a of the transmission-side camera 200 may transmit one image at a time with the same size as the resolution of the LCD panel 205 of the reception-side camera 200, but when the number of transmission target images is large. First, a list of thumbnails may be sent.

  When sending a list of thumbnails, the thumbnail list is sent for each page of the thumbnail list in which a plurality of thumbnail images are arranged on one page. In this case, when the thumbnail list page includes a plurality of pages, all the pages may be sent at a time. However, since the SDRAM 202 of the receiving camera 300 is often occupied, the pages are sent one page at a time. Is preferred. Then, the main CPU 201a of the transmission side camera 200 sends the thumbnail list for one page, and then converts the still image data of the image corresponding to the thumbnail image included in the page to the resolution of the LCD panel 205 of the reception side camera 300. The resolution is converted to the combined resolution, and the image data for display of the receiving camera 300 is transmitted one by one. At this time, the image data transmission time can be shortened by JPEG compression of the display image data to be transmitted.

  When an image is transmitted from the transmission-side camera 200 to the reception-side camera 300, information related to a pointer for indicating a target part of the image, for example, information related to a coordinate value of the pointer in the image is also transmitted. When the above-described thumbnail list is transmitted to the transmitting camera 300, information on the coordinate value of the pointer in the thumbnail list and information on the cursor frame indicating the selection status of the thumbnail image, that is, which thumbnail image is currently in the cursor frame Is also transmitted to the receiving camera 300.

  In the receiving camera 300, in step S14, the main CPU 201a expands the received JPEG compressed image and displays it on the LCD panel 205. Further, based on the received information regarding the pointer, the position indicated by the pointer in the image is specified, and the pointer is displayed at the position. Further, based on the information related to the cursor frame, the thumbnail image on which the cursor frame is hit is specified, and the thumbnail image is surrounded by the cursor frame.

  Thus, for example, when the thumbnail list displayed on the LCD panel 205 of the transmitting camera 200 shown in FIG. 5A is transmitted, the LCD of the receiving camera 300 as shown in FIG. 5B. Images displayed on the panel 205 can also be synchronized. Further, the pointer 5b and the cursor frame 5d are displayed on the LCD panel 205 of the receiving camera 300, and the pointer 5a and the cursor frame 5c displayed on the transmitting camera 200 can be synchronized.

  Note that pointer images to be displayed as pointers are recorded in the flash memories 203 of the transmission camera 200 and the reception camera 300, respectively. Therefore, if only the information on the pointer position is transmitted from the transmission side camera 200, the reception side camera 300 only needs to read and display the pointer image held by itself at the same position. For this reason, it is not necessary to transmit a pointer image from the transmitting camera 200 to the receiving camera 300, and the communication load can be reduced.

  For example, a pointer image as shown in FIG. 6 can be considered. That is, as shown in FIG. 6A, a pointer image having an arrow shape as a pointer shape, as shown in FIG. 6B, a pointer image having a pointer shape as an OR symbol shape, as shown in FIG. ), A pointer image in which the shape of the pointer is an angle symbol shape is conceivable. Further, as shown in FIG. 6D, a pointer image in which the pointer shape is an AND symbol shape, as shown in FIG. 6E, a pointer image in which the pointer shape is a circular shape, FIG. As shown in (), a pointer image in which the shape of the pointer is a crosshair shape can be considered.

  In the present embodiment, the pointer image stored in the flash memory 203 of the receiving camera 300 is a simple pointer image, for example, a cross-hair pointer image shown in FIG. The pointer image data speed can be increased by reducing the data amount of the pointer image. As a result, a cross-shaped pointer as shown in FIG. 5B is displayed on the LCD panel 205 of the receiving camera 300.

  In step S5, when the user operates the cross switch 2e to move the pointer 5a or the cursor frame 5c on the transmission side camera 200, the movement information of the pointer 5a from the transmission side camera 200 to the reception side camera 300 is displayed. Or movement information of the cursor 5c is transmitted. In the receiving camera 300, in step S15, the display controller 201d moves the pointer 5a or the cursor 5c based on the received movement information of the pointer 5a or the movement information of the cursor 5c. As a result, the display positions of the pointer 5a and the cursor 5c can be synchronized between the transmission-side camera 200 and the reception-side camera 300, and all persons can focus on the same part in the image.

  As described above, as the movement information of the pointer 5a or the movement information of the cursor 5c, the coordinate value after the movement of the pointer 5a or the cursor 5c or the movement direction and the movement amount of the pointer 5a or the cursor 5c are used. As a result, the amount of movement information of the pointer 5a or the movement information of the cursor 5c can be reduced, and the communication time can be shortened. Therefore, the movement speed of the pointer 5a or the cursor 5c of the receiving camera 300 is increased. It can be made.

  For example, when one image as shown in FIG. 7A is displayed on the LCD panel 205 of the sending camera 200, and the pointer 7a is moved to point to the position of the ball on the image, The movement information of the pointer 7a is transmitted to the receiving camera 300. As a result, as shown in FIG. 7B, the same image is displayed on the LCD panel 205 of the receiving camera 300, and the pointer 7b is further displayed at the same position. That is, the display contents of the transmission side camera 200 and the reception side camera 300 can be synchronized. As shown in FIG. 7, pointer images recorded in the respective flash memories 203 are used for the pointers 7a and 7b displayed on the transmitting camera 200 and the receiving camera 300, respectively. It has a different shape.

  In the present embodiment, the user can erase the display of the pointer and cursor displayed on the LCD monitor 205 in both the transmission-side camera 200 and the reception-side camera 300. For example, a function for erasing a pointer or cursor is assigned to any switch included in the operation switch 208, and when the user operates the switch, the display controller 201d erases the pointer or cursor being displayed. .

  When the user deletes the cursor or pointer on the transmission-side camera 200, the main CPU 201a transmits deletion information for instructing the reception-side camera 200 to delete the pointer. In the receiving camera 200, when this deletion information is received, the display controller 201d deletes the display of the cursor and pointer displayed on the LCD panel 205.

  Furthermore, the user can redisplay the pointer or cursor on the image by operating the same switch again. When the user redisplays the cursor or pointer on the transmitting camera 200, the main CPU 201a redisplays the pointer or cursor at the display position when the pointer or cursor is erased, and instructs redisplay. The redisplay information is transmitted to the receiving camera 200. In the receiving camera 200, when the redisplay information is received, the display controller 201d redisplays the cursor and the pointer at the display position at the time of deletion. Note that after the cursor or pointer is erased by the sending camera 200, it may be automatically displayed again after a predetermined time has elapsed.

  This makes it possible to synchronize the deletion or redisplay of the cursor or pointer between the transmission side camera 200 and the reception side camera 300. Further, if the cursor or pointer is continuously displayed even after grasping the part that the user is paying attention to, it is difficult to view the image and is troublesome, but this can be prevented.

  On the other hand, when the user deletes or redisplays the cursor or pointer on the receiving camera 300, only the receiving camera 300 deletes or redisplays the cursor or pointer display. Maintain the current state. In other words, even when the cursor display or the pointer display is erased or redisplayed by the reception side camera 300, the reflection to the transmission side 200 is not performed. This eliminates the possibility that the transmitting camera 200 loses sight of the part of interest.

  In step S6, the transmission-side camera 200 performs zoom display (enlarged display or reduced display) of the image based on an instruction from the user. For example, the operation switch 208 of the transmission-side camera 200 includes switches (for example, zoom switches 2g and 2h shown in FIG. 2B) to which a function for instructing enlargement display or reduction display of an image is assigned. It is. Further, the transmission-side camera 200 includes a resolution conversion module inside the image processing circuit 201b or the display controller 201d, and digital ZOOM is performed by changing the display resolution of the image with the resolution conversion module.

  When an image is zoomed and displayed on the transmission-side camera 200, the zoom information, for example, a zoom magnification such as an enlargement magnification or a reduction magnification is transmitted to the reception-side camera 300. On the other hand, the receiving-side camera 300 also includes a resolution conversion module. In step S16, an image is digitally ZOOMd by the resolution conversion module based on the received zoom information. Thereby, the zoom display of the image can be synchronized between the transmission side camera 200 and the reception side camera 300.

  The receiving camera 300 also includes a zoom switch, and the receiving camera 300 alone can enlarge or reduce an image by digital ZOOM. In this case, however, the zoom display on the receiving camera 300 side is not reflected on the transmitting camera 200, as in the case of the erasure and redisplay of the pointer. That is, it does not synchronize.

  FIG. 8 is a diagram illustrating a specific example when the image is zoomed and displayed on the receiving camera 300 when the zooming of the image is performed on the transmitting camera 200. On the LCD panel 205 of the transmission-side camera 200, as shown in FIG. 8A, an image is enlarged and displayed based on the point indicated by the pointer 7a based on an instruction from the user. In this case, as shown in FIG. 8B, an image enlarged at the same magnification is displayed on the LCD panel 205 of the receiving camera 300 with the point indicated by the pointer 7b as the center. In the example illustrated in FIG. 8, the example in which the image is enlarged around the point indicated by the pointer 7 a has been described. However, the present invention is not limited to this. For example, the center of the display range of the image displayed on the LCD panel 205 is described. You may make it expand centering on a point.

  In this way, when an image is digitally zoomed, the image quality deteriorates as the enlargement ratio (zoom magnification) increases. In this embodiment, in order to prevent image deterioration due to digital ZOOM, when the zoom magnification exceeds a predetermined magnification, the transmission-side camera 200 matches the larger image, that is, the resolution of the LCD panel 205. The enlarged image is generated using a still image having a higher resolution than that of the display image, and the generated enlarged image is transmitted again to the receiving camera 300. Here, the transmission side camera 200 keeps the data amount (number of bytes) of the enlarged image to be transmitted again to be approximately the same as the data amount of the image displayed so far, so that the transmission time for sending the enlarged image again is transmitted. To prevent the increase.

  Specifically, the image processing circuit 201b of the transmission-side camera 200 creates a new enlarged image as follows. Note that the size of the image to be transmitted to the receiving camera 300 does not have to be larger than the image size corresponding to the display resolution of the LCD panel 205 of the receiving camera 300, for example, the VGA size. Therefore, both the newly created enlarged image and the previously displayed image may be VGA size, and the amount of data (number of bytes) can be made substantially constant.

  The image processing circuit 201b of the transmission-side camera 200 is equivalently enlarged by placing the ZOOM center of high-resolution main image data (still image data) recorded in the memory card 204 at the center of the field of view and cutting out the inside thereof. Create an image. For example, if an image of VGA (640 × 480) size is cut out from the inside of a still image of 8M pixels (3264 × 2448), it is equivalently enlarged by “3264 ÷ 640 = 2448 ÷ 480 = 5.1” times. It will be. In this case, since the digital ZOOM is not performed, the image quality is the same as the original image.

  If this clipped image is transmitted to the receiving camera 300, an enlarged image having the same image quality as the original image can be displayed on the LCD monitor 205 of the receiving camera 300. Since the newly transmitted image has a higher image quality than the image displayed so far, even when the digital ZOOM is performed to enlarge the image, deterioration of the image can be suppressed. That is, it is possible to enlarge larger than the above-mentioned 5.1 times. If a high-quality enlarged image with a magnification lower than 5.1 times is desired, the image processing circuit 201b of the transmission-side camera 200 temporarily converts a still image of 8M pixels (3264 × 2448) to 7M pixels (3072 ×). 2304), 6M pixels (2816 × 2112), or 5M pixels (2592 × 1994), and the like, and the ZOOM center point is placed at the center of the field of view, and the inside thereof is cut out in VGA size.

  It should be noted that whether to perform the above-described digital ZOOM or to cut out and zoom from a high-resolution image may be specified by the user by mode selection, or only one method set in advance may be used. May be used.

  As shown in FIG. 8, when an image is enlarged by digital ZOOM, there are also effective pixels outside the field of view (screen). In such a case, the user can scroll the image and display the portion outside the field of view in both the transmission side camera 200 and the reception side camera 300. That is, in the sending camera 200 and the receiving camera 300, a scroll function is assigned to one of the switches included in the operation switch 208, and the user can scroll the image by operating the switch. .

  In step S7, when the image is scrolled by the user, the main CPU 201a of the transmission-side camera 200 transmits information regarding scrolling, for example, scroll information regarding the scroll direction and scroll amount, to the reception-side camera 300. In the receiving camera 300, in step S17, the display controller 201d scrolls the image based on the received scroll information.

  In step S17, when the user operates the operation switch 208 of the receiving camera 300 and the image is scrolled by the user, the display controller 201d displays the image based on the instruction from the user. Scroll. However, in this case as well, the scrolling on the receiving camera 300 side is not reflected on the transmitting camera 200, like the above-described deletion, redisplay, and zooming of the pointer. That is, it does not synchronize. In this way, when scroll information is received from the transmission-side camera 200 after the image is scrolled only by the reception-side camera 300, the display controller 201d discards the result of scrolling performed by the reception-side camera 300. Thus, synchronization with the transmission side camera 200 is established.

  In this way, the transmission side camera 200 as the initiator has the initiative of the operation, and the reception side camera 300 moves as a responder according to the instruction of the transmission side camera 200. That is, even if the operation is performed by the receiving camera 300 alone, when the operation is performed separately by the transmitting camera 200, the receiving camera 300 is moved according to the transmitting camera 200. Thereby, the display content of the LCD panel 205 of the receiving camera 300 can be reliably synchronized with the display content of the LCD panel 205 of the transmitting camera 200.

  FIG. 9 is a diagram illustrating a specific example when the zoomed enlarged image illustrated in FIG. 8 is scrolled. The LCD panel 205 of the sending camera 200 displays an image after the enlarged image shown in FIG. 8A is scrolled upward based on an instruction from the user, and the pointer 7a is a golfer's face. Point to the part. In this case, the scrolled image is displayed on the LCD panel 205 of the receiving camera 300 as shown in FIG. 9B, and the position of the pointer 7b is also synchronized.

  When the image is scrolled by the sending camera 200, the pointer 7a is left out of the field of view depending on the position of the pointer 7a displayed, the scroll direction and the scroll amount, and the image of the image that the user is paying attention to is displayed. There is a risk that the site will be lost. In the present embodiment, in order to avoid this, when the user moves the pointer 7a, the pointer 7a moves alone until the pointer 7a reaches the end of the field of view. When the pointer 7a is to be moved, the displayed image is also automatically scrolled in the same direction by being dragged by the movement of the pointer 7a.

  Thus, the image can be scrolled and the pointer 7a can be moved by a single operation, and the operation can be simplified. Furthermore, since the pointer 7a can always be in the field of view, the user is not losing sight of the portion of interest. The same applies when the pointer 7b is moved by the receiving camera 300. As described above, whether or not the movement of the pointer 7a and the scrolling of the image are linked can be specified by the user by the mode setting, or the movement of the pointer 7a and the scrolling of the image can always be linked. Good.

  In step S8, the main CPU 201a of the transmission-side camera 200 determines whether or not all images to be browsed selected by the user have been displayed. If a negative determination is made, the process returns to step S4, the frame advance instruction for displaying the next image is received by the user, and the next image is displayed. On the other hand, if an affirmative determination is made, the process proceeds to step S9, where the main CPU 201a of the transmission-side camera 200 sends an end command to the reception-side camera 300 and ends a series of operations. Thereafter, the relationship between the initiator and the responder up to that point is canceled, and it becomes possible for the receiving camera 300 that has been the responder to become an initiator to start the same operation.

  In the flowchart shown in FIG. 4, when data is transmitted from the transmission side camera 200 to the reception side camera 300, the reception side camera 300 always returns a response or a status to the transmission side camera 200. However, the smaller the response or status returned from the receiving camera 300, the higher the communication speed can be. Therefore, it is preferable that the receiving camera 300 does not return a response or status as much as possible, and returns a response or status only when necessary, for example, when a communication error occurs.

According to the present embodiment described above, the following operational effects can be obtained.
(1) The transmission-side camera 200 displays a display image generated based on still image data recorded in a memory card 204 as a recording medium on a monitor, displays a pointer on the image, and displays the displayed image. Image data and pointer data regarding the display position of the pointer are transmitted to the receiving camera 300. The receiving camera 300 receives the image data and pointer data from the transmitting camera 200, displays the received image on the monitor, specifies the pointer position on the image based on the pointer data, and displays the pointer at the specified position. I tried to do it. As a result, the contents displayed on the monitor can be synchronized between the transmitting camera 200 and the receiving camera 300, and many people can view the same image at the same time. In addition, by synchronizing the pointer positions, everyone can focus on the same part.

(2) When the pointer position is moved by the transmission-side camera 200, the movement information is transmitted to the reception-side camera 300, and the reception-side camera 300 moves the pointer based on the movement information. Thereby, even when the pointer is moved, the pointer position can be synchronized.

(3) Information on the coordinate value of the pointer after movement is transmitted as the movement information of the pointer. As a result, the amount of data to be transmitted can be reduced, and the communication load can be reduced.

(4) The shape of the pointer in the receiving camera 300 is set in advance. That is, the receiving camera 300 records a pointer image in the flash memory 203, reads it, and displays the pointer. As a result, it is not necessary to send a pointer image from the transmitting camera 200 to the receiving camera 300, and the communication load can be reduced.

(5) The user of the transmission side camera 200 can delete the displayed pointer, and when the pointer is deleted by the transmission side camera 200, the deletion information regarding the deletion is transmitted to the reception side camera 300. The pointer is also erased in the receiving camera 300. This makes it possible to synchronize pointer erasure.

(6) The sending camera 200 redisplays the pointer when a predetermined time has elapsed after erasing the pointer. This prevents the user from forgetting to redisplay the pointer, and prevents the user from losing sight of the site of interest.

(7) When the pointer is redisplayed by the transmission side camera 200, the information regarding the redisplay is transmitted to the reception side camera 300, and the reception side camera 300 also redisplays the pointer. This prevents the user of the receiving camera 300 from losing sight of the site of interest.

(8) When an image is zoomed by the transmitting camera 200, zoom information related to the zoom is transmitted to the receiving camera 300, and the receiving camera 300 zooms the image. As a result, both cameras can synchronize the zoom so that the same part can be enlarged and viewed in detail.

(9) When zooming with the transmission side camera, the image is enlarged or reduced around the display position of the pointer, or the image is displayed around the center point of the display range of the image displayed on the LCD panel 205. Enlarged or reduced. As a result, various zoom methods can be provided to the user.

(10) When the enlargement magnification during zooming is equal to or greater than a predetermined magnification, the transmitting camera 200 cuts out an image whose display range is equivalent to the enlarged display image from the original image, that is, the still image data. Thus, the data is transmitted to the receiving camera 300. As a result, it is possible to prevent deterioration in image quality due to digital zoom and display a high-quality enlarged image.

(11) When an image is scrolled by the transmission side camera 200, information related to the scroll is transmitted to the reception side camera 300, and the reception side camera 300 scrolls the image based on the received information. As a result, both cameras can synchronize scrolling.

(12) In the transmission-side camera 200, when the user moves the pointer, if the pointer is moved out of the field of view, that is, toward the outside of the screen, the image is scrolled in the moving direction. The scroll information is transmitted to the receiving camera 300. As a result, the image can be scrolled while the pointer is always in the field of view, and it is possible to prevent the user from losing sight of the part of interest.

(13) When the receiving camera 300 is instructed to delete the pointer, only the receiving camera 300 deletes the pointer and the transmitting camera 200 does not delete the pointer. In addition, when the reception side camera 300 is instructed to zoom the image, only the reception side camera 300 is zoomed, and the transmission side camera 200 is not zoomed. When the receiving camera 300 is instructed to scroll the image, only the receiving camera 300 is scrolled, and the transmitting camera 200 is not scrolled. As a result, it is possible to prevent the display content of the transmission-side camera 200 as an initiator from being affected by an operation performed on the reception-side camera 300 as a responder.

-Modification-
Note that the display image synchronization system of the above-described embodiment can be modified as follows.
(1) In the above-described embodiment, the example in which the information on the coordinate value of the pointer in the image is transmitted from the transmitting camera 200 to the receiving camera 300 as the information on the pointer has been described. However, information necessary for synchronizing other pointer positions, for example, the movement direction and movement amount of the pointer may be transmitted as information related to the pointer.

(2) In the above-described embodiment, the transmitting camera 200 displays the images selected by the user one by one by the frame advance operation by the user, and the display image and the pointer position with the receiving camera 300. An example of taking the synchronization has been described. However, when the transmission-side camera 200 is equipped with a slideshow playback function, it plays back while automatically switching the image selected by the user. Then, the transmission side camera 200 transmits the image selected by the user to the reception side camera 300 in a predetermined cycle according to the display order. In the receiving camera 300, the display content of both cameras may be synchronized by displaying the image received from the transmitting camera 200 on the LCD monitor 205, as in the above-described embodiment.

  When such a slide show synchronous playback is performed, there is a problem that synchronization cannot be achieved if the user of the receiving camera 300 attempts to extend or enlarge the display time of the slide show image. Therefore, the receiving camera 300 allows the user to stop the slide show reproduction by operating a predetermined switch, and when the reproduction is stopped by the user, information on the stop is transmitted to the transmitting camera 200. Send to. When the transmission-side camera 200 receives the information regarding the stop, the transmission-side camera 200 stops the transmission of images to the reception-side camera 300 and stops the slide show reproduction on the transmission-side camera 300. That is, the image displayed at that time is continuously displayed on the LCD panel 205 of the transmitting camera 200.

  In the transmission-side camera 200 and the reception-side camera 300, in the state where the slide show is stopped as described above, that is, in the state where one image being reproduced is displayed on the LCD monitor 205, the user can move the pointer as described above. Movement, zoom display, and scrolling can be performed. When these operations are performed by the transmission side camera 200, the information is transmitted to the reception side camera 300 to synchronize the display contents. Thereafter, when the stop of the slide show is canceled by the user at the reception side camera 300, information regarding the cancellation is transmitted to the transmission side camera 200, and the transmission side camera 200 reproduces the slide show and the image to the reception side camera 300. Resume transmission.

  In addition, the transmission side camera 200 can also stop the slide show. In this case, the transmission side camera 200 stops the slide show and stops transmission of images to the reception side camera 300. Thereby, even when the slide show is stopped by the transmission side camera 200, the synchronization can be achieved.

(3) In the above-described embodiment, an example in which an image recorded in the transmission-side camera 200 is sent to the reception-side camera 300 and display contents are synchronized between both cameras has been described. However, if a user viewing an image on the receiving camera 300 has a favorite image among the displayed images, the user can capture the image on the receiving camera 300 and save it on the memory card. It may be.

  Therefore, an image ID for uniquely identifying each image is added to each image transmitted from the transmitting camera 200 to the receiving camera 300. When an image is transmitted from the sending camera 200 to the receiving camera 300, the image ID of the image is recorded in the flash memory 203 of the sending camera 200 and the flash memory 203 of the receiving camera 300, respectively. The receiving camera 300 records the received image in the flash memory 203 until the image ID is deleted by the user. On the other hand, when the image ID is deleted by the user, the image corresponding to the deleted image ID is deleted from the flash memory 203.

  Thus, until the user of the receiving camera 300 deletes the image ID, the image received in the past can be recorded in the flash memory 203, and the user of the receiving camera 300 likes it. Images can be selected and recorded on the memory card 204. In addition to this image ID, if you also record basic information such as the serial number of the sending camera 200 and the receiving camera 300 and the transmission date and time of the image in the flash memory 203, you can watch the image with whom. The convenience for the user is improved. These information and image ID may be recorded on the memory card 204 instead of the flash memory 203.

  Further, the user can select a desired thumbnail image from the displayed thumbnail images while browsing the thumbnail image with the receiving camera 300. Then, the main CPU 201a of the reception-side camera 300 may request the transmission-side camera 200 to transmit still image data corresponding to the thumbnail image selected by the user. At this time, the image ID of the still image data requesting transmission is sent from the receiving camera 300 to the transmitting camera 200. In the transmitting camera 200, the main CPU 201 a transmits still image data corresponding to the image ID received from the receiving camera 300 to the receiving camera 300. As a result, the user can acquire still image data of a desired image from the transmission-side camera 200.

(4) In the above-described embodiment, an example in which an image is transmitted from the transmission-side camera 200 to the reception-side camera 300 and images displayed on both sides are synchronized has been described. However, if the digital camera used in the present invention can reproduce audio data and music data together with image display, the audio data and music data may be reproduced while synchronizing the displayed image. Good.

  At this time, as in the case of synchronizing the images displayed in the above-described embodiment, the transmitting camera 200 reproduces audio data and music data, and transmits the data to the receiving camera 300 for reception. The side camera 300 may reproduce the received audio data and music data. Alternatively, the voice data or music data to be played back may be played back by each camera without synchronizing the voice data and music data to be played back.

  However, as in the above-described embodiment, when a plurality of users have the transmission camera 200 and the reception camera 300 to view images simultaneously, the distance between the transmission camera 200 and the reception camera 300 is short. Probability is high. In such a case, audio data or music data is recorded in the flash memory 203 or the memory card 204 of either the transmission side camera 200 or the reception side camera 300, and the displayed image is synchronized. In parallel, audio data or music data may be reproduced by either one of the cameras. Alternatively, audio data and music data are recorded in both the transmission-side camera 200 and the reception-side camera 300, and the user of the transmission-side camera 200 and the user of the reception-side camera 300 consult with each camera. It is only necessary to select and play a favorite voice or music recorded in the.

  As a result, the images displayed between the sending camera 200 and the receiving camera 300 can be synchronized, and voice and music can be played back, so that the user can enjoy the image while enjoying it. become.

  Note that the present invention is not limited to the configurations in the above-described embodiments as long as the characteristic functions of the present invention are not impaired.

It is a block diagram which shows the structure of one Embodiment of a display image synchronization system. It is the figure which showed typically the example of a structure of the display image synchronization system 100 in case the receiving side camera 300 is one. 2 is a block diagram illustrating a configuration of an embodiment of a transmission camera 200 and a reception camera 300. FIG. FIG. 6 is a flowchart showing processing of a transmission side camera 200 and a reception side camera 300. It is a figure which shows the specific example in the case of taking the synchronization of a thumbnail list and a cursor position. It is a figure which shows the specific example of a cursor shape. It is a figure which shows the specific example in the case of taking the synchronization of an image and a pointer position. It is a figure which shows the example of a synchronization at the time of displaying an enlarged image. It is a figure which shows the example of a synchronization at the time of scrolling an image.

Explanation of symbols

100 display image synchronization system, 200 transmitting camera, 201 DSC engine, 201a main CPU, 201b image processing circuit, 201c JPEG codec, 201d display controller, 201e Audio codec, 201f SIO, GPIO, 202 SDRAM, 203 flash memory, 204 memory Card, 205 LCD panel, 206 Crystal oscillator (X'tal), 207 Speaker, 208 Operation switch, 209 Shooting lens, 210 Image sensor (CCD), 211 AFE, 300 Receiver camera

Claims (24)

The display for display on a display device included in each device, between a transmission-side device having an original image recorded on a recording medium and a display image generated based on the original image, and a reception-side device A display image synchronization program for synchronizing images,
In order for the computer to function as the transmitting device, the computer
A display control procedure for outputting and displaying the display image and a pointer for pointing to an arbitrary position in the display image on a display device (transmission-side display device) included in the transmission-side device;
The display image data (image data) output on the transmission side display device and the data (pointer data) relating to the display position of the pointer in the display image are transmitted to the receiving side device of the communication partner. Execute the sending procedure,
In order for the computer to function as the receiving device, the computer
A reception procedure for receiving the image data and the pointer data transmitted from the transmission-side device of the communication partner;
Output the image data received in the reception procedure to the display device (reception side display device) provided in the reception side device to display the display image, based on the pointer data received in the reception procedure, A display image synchronization program for specifying a display position of the pointer in the display image and executing a reception data display procedure for displaying the pointer at the specified position. In the display image synchronization program according to claim 1,
In order for the computer to function as the transmitting device, the computer
Further executing a pointer movement control procedure for moving the pointer in the display image based on an instruction from a user of the transmitting device;
The transmission procedure transmits the movement information of the pointer to the receiving device of the communication partner,
The received data display procedure moves the pointer in the display image based on the movement information of the pointer received in the reception procedure. In the display image synchronization program according to claim 2,
The display procedure is characterized in that either the coordinate value after movement of the pointer or the movement direction and movement amount of the pointer is transmitted to the receiving device of the communication partner as the movement information of the pointer. Synchronous program. In the display image synchronization program according to any one of claims 1 to 3,
The shape of the pointer in the receiving device is preset,
In the received data display procedure, the pointer having the preset shape is drawn at the display position of the pointer in the specified display image. In the display image synchronization program according to any one of claims 1 to 4,
In order for the computer to function as the transmitting device, the computer
Based on an instruction from a user of the transmission-side device, further causing a transmission-side pointer erasure procedure for erasing the pointer displayed in the display image,
The transmission procedure transmits erasure information for instructing erasure of the pointer to the receiving device of the communication partner,
The received data display procedure erases the pointer displayed in the display image based on the erase information of the pointer received in the reception procedure. In the display image synchronization program according to claim 5,
The display control procedure is characterized in that, when the pointer is erased by the transmission side pointer erasure procedure, the pointer is displayed again at the display position at the time of erasure after a predetermined time has elapsed. In the display image synchronization program according to claim 6,
In the transmission procedure, when the pointer is redisplayed by the display control procedure, redisplay information for instructing the redisplay is transmitted to the receiving device of the communication partner,
The received data display procedure redisplays the pointer at a display position at the time of erasure based on the redisplay information of the pointer received in the reception procedure. In the display image synchronization program according to any one of claims 1 to 7,
In order for the computer to function as the receiving device, the computer
A display image synchronization program for further executing a receiving side pointer erasing procedure for erasing the pointer displayed in the display image based on an instruction from a user of the receiving side device. In the display image synchronization program according to any one of claims 1 to 8,
In order for the computer to function as the transmitting device, the computer
Performing resolution conversion on the display image displayed on the transmission-side display device to further execute a transmission-side digital zoom procedure for enlarging or reducing the display image;
The transmission procedure transmits zoom information related to an enlargement or reduction ratio of the display image to the receiving device of the communication partner,
The display data synchronization program characterized in that the received data display procedure enlarges or reduces the display image displayed on the receiving display device based on zoom information of the display image received in the reception procedure. . In the display image synchronization program according to claim 9,
The transmission-side digital zoom procedure includes a first zoom mode for enlarging or reducing the image around the display position of the pointer in the display image, and a range of the display image displayed on the transmission-side display device. A display image synchronization program that selects any one of the second zoom modes for enlarging or reducing the image around the center position of the image and enlarging or reducing the display image. In the display image synchronization program according to claim 9 or 10,
In order for the computer to function as the receiving device, the computer
A display image synchronization program that further performs a receiving-side digital zoom procedure for performing resolution conversion on the display image displayed on the receiving-side display device to enlarge or reduce the image. In the display image synchronization program according to claim 11,
The receiving-side digital zoom procedure includes a first zoom process for enlarging or reducing the image around the display position of the pointer in the display image, and a range of the display image displayed on the receiving-side display device. A display image synchronization program for enlarging or reducing the display image by any one of the second zoom processes for enlarging or reducing the image around the center position of the image. In the display image synchronization program according to any one of claims 9 to 12,
The transmitting-side digital zoom procedure cuts out an enlarged display image whose image display range is equivalent to the enlarged display image from the original image when the enlargement magnification of the display image is equal to or larger than a predetermined magnification. ,
The display control procedure displays the enlarged display image on the transmission side display device,
The transmission procedure transmits the image data of the enlarged display image to the receiving-side device of the communication partner,
The received data display procedure outputs the image data of the enlarged display image received in the reception procedure to the display device on the receiving side and displays it. In the display image synchronization program according to any one of claims 1 to 13,
In order for the computer to function as the transmitting device, the computer
Based on an instruction from a user of the transmission-side device, further causing a transmission-side scroll procedure for scrolling the display image displayed on the transmission-side display device,
The transmission procedure transmits scroll information related to the scrolling of the display image to the receiving device of the communication partner,
The display data synchronization program, wherein the reception data display procedure scrolls the display image displayed on the reception-side display device based on the scroll information received in the reception procedure. In the display image synchronization program according to claim 14,
In the transmitting side scrolling procedure, when the pointer is moved in the direction outside the screen of the transmitting side display device in the pointer movement control procedure, the display image is scrolled in the moving direction,
The transmission procedure transmits scroll information related to the scrolling of the display image to the receiving device of the communication partner,
The display data synchronization program, wherein the reception data display procedure scrolls the display image displayed on the reception-side display device based on the scroll information received in the reception procedure. In the display image synchronization program according to claim 14 or 15,
In order for the computer to function as the receiving device, the computer
Based on an instruction from a user of the receiving side device, further causing a receiving side scrolling procedure of scrolling the display image displayed on the transmitting side display device;
In the reception data display procedure, when the reception procedure receives the scroll information from the transmission side device, the scroll result based on the reception side scroll procedure is discarded and the scroll based on the scroll information is performed. Display image synchronization program. In the display image synchronization program according to any one of claims 1 to 16,
In order for the computer to function as the transmitting device, the computer
Among the display images recorded on the recording medium, a plurality of display images selected by a user of the transmission-side device are sequentially displayed on the transmission-side display device at predetermined time intervals, and a slide show is executed. To further execute the slideshow execution procedure
The transmission procedure transmits the image data of the plurality of display images selected by a user of the transmission-side device to the reception-side device of the communication partner at the predetermined time interval and order,
The display data synchronization program characterized in that the received data display procedure performs a slide show by switching and displaying on the receiving display device each time the image data of the plurality of display images is received by the receiving means. In the display image synchronization program according to claim 17,
The slide show execution procedure stops the slide show being executed on the transmission side display device when a stop of the slide show is instructed by a user of the transmission side device,
In the reception data display procedure, the slide show that is being executed on the reception-side display device is stopped in response to the reception of the image data of the plurality of display images in the reception procedure being stopped. Display image synchronization program. In the display image synchronization program according to any one of claims 1 to 18,
In order for the computer to function as the receiving device, the computer
A selection procedure for selecting a display image designated by a user from among the display images based on the image data received in the reception procedure;
And further executing an original image request procedure for transmitting, to the receiving device, original image request information for requesting transmission of the original image corresponding to the display image selected by the selection procedure to the receiving device. Display image synchronization program characterized by the above. In the display image synchronization program according to claim 19,
In order for the computer to function as the transmitting device, the computer
A request receiving procedure for receiving the original image request information;
A display image synchronization program for further executing an original image transmission procedure for transmitting the requested original image to the receiving side device based on the original image request information received in the request reception procedure. In the display image synchronization program according to any one of claims 1 to 20,
In order for the computer to function as the transmitting device, the computer
A display image synchronization program for further executing a transmission side reproduction procedure for reproducing audio data or music data when the display image is displayed on the transmission side image display device. In the display image synchronization program according to any one of claims 1 to 21,
In order for the computer to function as the receiving device, the computer
A display image synchronization program for further executing a reception side reproduction procedure for reproducing audio data or music data when the display image is displayed on the reception side image display device.   23. A digital camera comprising execution means for executing the display image synchronization program according to claim 1 and functioning as the transmission-side device or the reception-side device.   24. A display image synchronization system including one digital camera according to claim 23 that functions as a transmission side device and at least one digital camera according to claim 23 that functions as a reception side device.

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