JP2005073050A - Picture data transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a picture data transmitting method capable of transmitting economical picture data by simultaneously automatically transmitting a moving picture image and divided still picture images, uniting the divided still picture images at the time of display and performing monitoring operation with high efficiency. <P>SOLUTION: A picture data transmission system is provided with a picture data transmitter 1 provided with an imaging part 2 for photographing a moving picture and a still picture and a picture data receiver 13 provided with a display part 23 for periodically displaying still pictures. The picture data transmitter 1 configures a radio signal to be transmitted, wherein each signal frame consists of moving picture data and divided still picture data following the moving picture data, always displays a moving picture based on moving picture data for each signal frame and displays a still picture obtained by uniting the divided still picture data for each signal frame into a single body at a constant period when a picture data receiver 13 displays picture data on a display part 23. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an image data transmission system that wirelessly transmits image data between an image data transmission device and an image data reception device, and in particular, when transmitting a moving image and a still image captured by an image data transmission device as wireless signals. The present invention relates to an image data transmission system in which a signal frame is composed of moving image data and subsequent still image data, and an image data receiving device always displays a moving image and displays a still image at a constant period.

  In recent years, it consists of an image data transmitting device and an image data receiving device, and the image data transmitting device is arranged at a monitoring location or the like separated from the image data receiving device, and an image signal is transmitted from the image data transmitting device to a communication such as a wireless LAN or the Internet. 2. Description of the Related Art An image data transmission system has been developed that transmits to an image data receiving device through a network, and the image data receiving device displays the received image data on a display unit. In this type of image data transmission system, the image data transmission device side forms image data obtained by photographing the monitored object as a moving image, and the formed image data is transmitted as a transmission signal to the image data reception device side through a communication network. When the image data receiving device receives this transmission signal, it reproduces the image data from the transmission signal, and displays the reproduced image data as a moving image or a part of the moving image as a still image on the display unit. The image data receiving apparatus can monitor or confirm the status of a monitoring object at a monitoring location separated from the receiving apparatus from time to time.

  Such a known image data transmission system is an image data transmission device that forms image data obtained by photographing a monitored object as a moving image, transmits the formed image data as a transmission signal to the image data reception device side through a communication network, and the image data The receiving device reproduces the image data from the received transmission signal, and displays the image data as a moving image or a part thereof as a still image on the display unit. Can recognize the situation. However, this type of image data transmission system has a relatively narrow frequency range of image data handled by the image data transmission device and the image data reception device, including a photographing unit such as a camera. As a result, not only the resolution of the moving image displayed on the image data receiving device is lowered, but also the resolution of the still image on which a portion of the moving image is displayed is lowered, and the image data is received. When the device side tries to recognize the detailed state of the monitoring object, an undesired situation may occur in which it is difficult to perform such recognition.

  In order to avoid the occurrence of an unfavorable situation in such a known image data transmission system, the monitoring object is photographed as a high-resolution still image or a low-resolution moving image by the image data transmission device, and represents a still image of the photographed subject. The image data representing the image data and the moving image is selectively transmitted to the communication network, and the image data receiving device receives the image data representing the still image and the image data representing the moving image received from the communication network, and the reproduced image data. Has been proposed, an image data transmission system has been proposed in which a still image is displayed at a high resolution and a moving image is displayed at a low resolution. Japanese Patent Application Laid-Open No. 2003-87774 discloses an example. Mention may be made of the disclosed image data acquisition system.

  The image data acquisition system disclosed in Japanese Patent Application Laid-Open No. 2003-87774 includes an on-site terminal device that is an image data transmitting device and an operating-side terminal device that is an image data receiving device. The side terminal device is selectively connected through the Internet, which is a communication network, and image data from the site side terminal device is transmitted to the operation side terminal device through the Internet.

  Here, FIG. 6 shows a configuration of such an image data acquisition system, and is a schematic diagram showing a main part thereof.

  As shown in FIG. 6, the image data acquisition system includes a site-side terminal device 50, an operation-side terminal device 60, the Internet 70, and routers 71 and 72. In this case, the site-side terminal device 50 includes an imaging unit 51 such as a camera, an image data communication unit 52, an audio signal communication unit 53, an operation control unit 54, and a LAN card 55. The device 60 includes a display unit 61, an operation unit 62, an image data communication unit 63, an audio signal communication unit 64, an operation control unit 65, and a storage unit 66. In this case, the imaging unit 51 always shoots a moving image of the shooting range of the subject with a low resolution, but when there is an instruction from the operation side terminal device 60, the still image of the shooting range of the subject is temporarily displayed. The picture is taken at a high resolution.

  The image data acquisition system having the above-described configuration generally operates as follows.

  First, when the image data communication unit 63 of the operation side terminal device 60 is connected to the image data communication unit 52 of the site side terminal device 50 through the Internet 70, operation control is performed between the site side terminal device 50 and the operation side terminal device 60. By operating the unit 65 and the like, various types of data are exchanged, and accordingly, the imaging range of the subject imaged by the imaging unit 51 of the on-site side terminal device 50 and the display unit 61 of the operating side terminal device 60 are displayed. The image display range is set. After these settings are made, the imaging unit 51 of the site side terminal device 50 images the subject based on these settings, forms image data representing the moving image, and uses the formed image data as a transmission signal for image data. The data is transmitted from the communication unit 52 to the operation side terminal device 60 through the Internet 70. At this time, when the image data communication unit 63 of the operation side terminal device 60 receives this transmission signal, the image data in the received signal is reproduced, and the reproduced image data is supplied to the display unit 61 and displayed as a moving image. The

  When such a moving image is displayed on the display unit 61, the operation-side terminal device 60 operates the operation unit 62 to specify the imaging of the still image and simultaneously specify the imaging range of the subject in the still image. The imaging unit 51 of the on-site terminal device 50 captures a still image of the subject according to the designation. Then, the site side terminal device 50 forms image data representing the captured still image, and transmits the formed image data as a transmission signal from the image data communication unit 52 to the operation side terminal device 60 through the Internet 70. Also at this time, when the image data communication unit 63 of the operation side terminal device 60 receives this transmission signal, the image data in the received signal is reproduced, and the reproduced image data is supplied to the display unit 61, and as a still image. Is displayed.

Normally, the shooting time of a still image in the imaging unit 51 of the field side terminal device 50 ends when a single still image is shot, and then image data representing a moving image is shot again. When the imaging unit 51 captures a still image again, it is only necessary to specify the imaging of the still image and the imaging range of the subject in the still image as described above.
JP 2003-87774 A

  By the way, the image data acquisition system disclosed in the Japanese Patent Application Laid-Open No. 2003-87774 transmits image data having a low resolution when the field side terminal device 50 forms image data representing a moving image of a subject, On the other hand, when forming image data representing a still image of a subject, it is transmitted as image data having a high resolution. For this reason, when the image data received by the operation side terminal device 60 is displayed on the display unit 61, the moving image cannot be displayed so clearly, but the still image is displayed with high definition. Thus, the detailed state of each part of the subject can be recognized.

  However, the image data acquisition system disclosed in Japanese Patent Application Laid-Open No. 2003-87774 is required to display a single still image each time a still image is to be displayed on the display unit 61 of the operation side terminal device 60. In addition, it is necessary to operate the operation unit 62, thereby specifying the still image capturing and the subject imaging range in the still image. That is, the operation-side terminal device 60 makes a dedicated operator resident on the operation-side terminal device 60 when displaying the still image on the display unit 61 in a short period or repeatedly over a certain period. In this respect, it is difficult to perform the monitoring operation of the operation side terminal device 60 with high efficiency, and it is not possible to be an economical system because it requires manpower.

  The present invention has been made in view of such a technical background, and an object of the present invention is to automatically transmit a moving image and a divided still image simultaneously and integrate the divided still image at the time of display. Another object of the present invention is to provide an image data transmission method capable of performing monitoring work with high efficiency and economically transmitting image data.

  In order to achieve the above object, an image data transmission system according to the present invention comprises an image data transmission device that transmits a wireless signal and an image data reception device that receives and displays the wireless signal. An image capturing unit that generates image data obtained by shooting, an image data compression processing unit that encodes image data to generate compressed image data, an image data holding unit that temporarily stores image data and compressed image data, and a compression A radio signal transmission / reception unit that transmits image data as a radio signal and a control unit that controls the operation of the image data transmission device. The image data reception device receives a radio signal and generates compressed image data. The image data reproduction processing unit for decoding the compressed image data and reproducing the original image data, and the compressed image data and the image data An image data holding unit, a display unit for displaying reproduced image data, and a control unit for controlling the operation of the image data receiving device. The image data transmitting device transmits from the radio signal transmitting / receiving unit. The radio signal is configured such that each signal frame is composed of moving image data followed by divided still image data, and the moving image data for each signal frame is displayed when the image data receiving device displays the image data on the display unit. And a means for displaying a still image obtained by integrating the still image data divided for each signal frame at a constant period.

  In this case, the resolution of the still image in the means is provided with a first configuration set to be higher than the resolution of the moving image.

  Each of the radio signal transmission / reception units in the means has a second configuration that is a short-range radio communication module.

  According to the present invention, in the image data transmitting apparatus, the radio signal transmitted from the radio signal transmitting / receiving unit is configured such that each signal frame is composed of moving image data and subsequent divided still image data. When displaying image data on the display unit, a still image obtained by constantly displaying a moving image based on the moving image data for each signal frame and integrating the divided still image data for each signal frame Is displayed at a fixed cycle, so that the video data and the still image data are automatically transmitted simultaneously from the image data transmission device, and the video data can always be displayed when the image data reception device displays the image. In addition, still image images can be displayed at regular intervals, the subject can be monitored with high efficiency, and image data can be transmitted economically. There is an effect that it is possible to.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 and 2 show the best mode for carrying out the image data transmission system according to the present invention, and are block diagrams showing the configuration of the main part thereof. FIG. 1 shows an image data transmitting apparatus, and FIG. Represents an image data reception device.

  As shown in FIG. 1, an image data transmitting apparatus 1 according to this embodiment captures a moving image and a still image of a subject, and outputs an image signal for moving image and a still image signal, and an imaging unit 2 A first memory (memory 1) 3 that temporarily stores the image signal for moving image captured in step 2; a second memory (memory 2) 4 that temporarily stores the image signal for still image captured by the image capturing unit 2; A low-resolution encoder 5 that compresses a moving image signal and converts it to a moving image compressed image signal, a high-resolution encoder 6 that compresses a still image signal and converts it to a still image compressed image signal, and a moving image compressed image A first buffer memory (buffer memory 1) 7 for temporarily storing signals, a second buffer memory 8 for temporarily storing still image compressed image signals, a moving image compressed image signal, and a still image compressed image signal Synthesize and compress A compressed image signal synthesizing unit 9 that forms an image signal, a frequency conversion of the synthesized compressed image signal into a radio signal of a high frequency, and transmitting the radio signal from the transmission / reception antenna 10 (1), for example, Bluetooth (registered trademark); A short-range wireless communication module (BT module) 10 called, a control unit 11 that performs overall control of operations of each unit of the image data transmission device 1, and a plurality of operable operating bodies, and selectively operates these operating bodies. And an operation unit 12 for giving various instructions to the image data transmitting apparatus 1.

  As shown in FIG. 2, the image data receiving device 13 according to this embodiment reproduces a composite compressed image signal from a radio signal received by the transmission / reception antenna 14 (1), for example, Bluetooth (registered trademark) A short-range wireless communication module (BT module) 14 called, a compressed image signal distribution unit 15 that distributes the combined compressed image signal into a compressed image signal for moving images and a compressed image signal for still images, and temporarily stores the compressed image signals for moving images The first buffer memory (buffer memory 1) 16 to be stored in the memory, the second buffer memory (buffer memory 2) 17 to temporarily store the still image compressed image signal, and the compression of the moving image compressed image signal are released. The low-resolution decoder 18 that reproduces the original video image signal and the compressed still image compression image signal are decompressed, and the original still image signal is restored. A high-resolution decoder 19, a first memory (memory 1) 20 that temporarily stores a moving image signal, a second memory (memory 2) 21 that temporarily stores a still image signal, and a moving image The image signal selection unit 22 that selects and outputs an image signal or an image signal for still image, the display unit 23 that displays the supplied image signal as a moving image or still image, and the operation of each unit of the image data receiving device 13 The control unit 24 includes a control unit 24 that performs overall control, and an operation unit 25 that includes a plurality of operable operation bodies and selectively operates these operation bodies to give various instructions to the image data receiving device 13.

  In the image data transmitting apparatus 1, the imaging unit 2 has a moving image output end connected to the input end of the first memory 3, a still image output end connected to the input end of the second memory 4, and a control end connected to the control unit. 11 is connected. The first memory 3 has an output end connected to the input end of the low resolution encoder 5 and a control end connected to the control unit 11. The second memory 4 has an output end connected to the input end of the high resolution encoder 6 and a control end connected to the control unit 11. The low resolution encoder 5 has an output end connected to the input end of the first buffer memory 7 and a control end connected to the control unit 11. The high resolution encoder 6 has an output end connected to the input end of the second buffer memory 8 and a control end connected to the control unit 11. The first buffer memory 7 has an output end connected to the first input end of the compressed image signal synthesis unit 9 and a control end connected to the control unit 11. The second buffer memory 8 has an output terminal connected to the second input terminal of the compressed image signal synthesis unit 9 and a control terminal connected to the control unit 11. The compressed image signal synthesis unit 9 has an output end connected to the input end of the short-range wireless communication module 10 and a control end connected to the control unit 11. The short-range wireless communication module 10 has an output end connected to the transmission / reception antenna 10 (1) and a control end connected to the control unit 11. The operation unit 12 has an operation signal output terminal connected to the control unit 11.

  In the image data receiving device 13, the short-range wireless communication module 14 has an input end connected to the transmission / reception antenna 14 (1), an output end connected to the input end of the compressed image signal distribution unit 15, and a control end controlled. Connected to the unit 24. The compressed image signal distribution unit 15 has a moving image output end connected to the input end of the first buffer memory 16, a still image output end connected to the input end of the second buffer memory 17, and a control end connected to the control unit 24. The The first buffer memory 16 has an output terminal connected to the input terminal of the low resolution decoder 18 and a control terminal connected to the control unit 24. The second buffer memory 17 has an output end connected to the input end of the high resolution decoder 19 and a control end connected to the control unit 24. The low resolution decoder 18 has an output terminal connected to the input terminal of the first memory 20 and a control terminal connected to the control unit 24. The high resolution decoder 19 has an output terminal connected to the input terminal of the second memory 21 and a control terminal connected to the control unit 24. The first memory 20 has an output terminal connected to the first input terminal of the image signal selection unit 22 and a control terminal connected to the control unit 24. The second memory 21 has an output end connected to the second input end of the image signal selection unit 22 and a control end connected to the control unit 24. The image signal selection unit 22 has an output end connected to the input end of the display unit 23 and a control end connected to the control unit 24. The control unit of the display unit 23 is connected to the control unit 24.

  In this case, in the embodiment shown in FIG. 1 and FIG. 2, an example in which a Bluetooth module is used for each of the short-range wireless communication modules 10 and 14 is given, but the short-range wireless communication modules 10 and 14 according to the present invention are given. Of course, is not limited to the Bluetooth module, and may be another wireless communication module that performs the same function.

  3 is a flowchart showing the operation history of the image data transmitting apparatus 1 shown in FIG. 1, and FIG. 4 is a flowchart showing the operation history of the image data receiving apparatus 13 shown in FIG. . FIG. 5 is an image data configuration diagram showing image data transmitted as a radio signal from the image data transmitting apparatus 1.

  The radio signal used in this image data transmission system has a configuration as shown in FIG. 5 and consists of a predetermined amount of moving image data D and subsequent still image data S for each signal frame F. In the case of the still image data S, the still image data constituting one displayed still image is equally divided, for example, divided into 12 equal parts, and the still image data divided into 12 equal parts each time the signal frame F arrives. The images are transmitted in order, and the still image data divided into 12 equal parts at the time of display are combined and displayed as one still image.

  First, the operation of the image data transmitting apparatus 1 according to this embodiment will be described using the flowchart shown in FIG.

  First, in step S1, the control unit 11 determines whether or not the timing at which the imaging unit 2 captures a still image has come. When it is determined that the timing for capturing a still image has not yet arrived (N), the process proceeds to the next step S2, while when it is determined that the timing for capturing a still image has not yet arrived (Y) The process proceeds to another step S6.

  Next, in step S2, the control unit 11 does not have a timing for capturing a still image with the image capturing unit 2, and thus controls the image capturing unit 2 to capture a moving image. One memory 3 is sequentially stored.

  Next, in step S3, when the control unit 11 determines that the moving image signal stored in the first memory 3 has reached a predetermined amount, the controller 11 reads the moving image signal and reads the read moving image signal with a low resolution. It is supplied to the encoder 5 and compressed, and converted into a compressed image signal for moving images.

  Subsequently, in step S <b> 4, the control unit 11 sequentially stores the compressed image signal for moving image formed by the low resolution encoder 5 in the first buffer memory 7.

  In step S5, when a predetermined amount of the moving image compressed image signal is stored in the first buffer memory 7, the control unit 11 reads out the moving image compressed image signal for each frame, and reads the read moving image compressed image signal. Is supplied to the compressed image signal synthesizing unit 9 as moving image data, and divided still image data, which will be described later, is added to form one frame of image data. The obtained image data is converted into a high-frequency signal in the short-range wireless communication module 10. The frequency is converted into a radio signal and transmitted from the transmitting / receiving antenna 10 (1).

  On the other hand, in step S6, since it is time to shoot a still image with the imaging unit 2, the control unit 11 controls the imaging unit 2 to shoot one still image, and for the obtained still image. Image signals are sequentially stored in the second memory 2.

  Next, when the control unit 11 determines in step S7 that the still image signal stored in the first memory 3 has reached a predetermined amount, the control unit 11 reads the still image signal and reads the read still image image. The signal is supplied to the high resolution encoder 6 to be compressed and converted into a still image compressed image signal.

  Next, in step S <b> 8, the control unit 11 sequentially stores the still image compressed image signal formed by the high resolution encoder 6 in the second buffer memory 8.

  Subsequently, in step S9, the control unit 11 determines whether or not the transmission timing for transmitting the still image has arrived. When it is determined that the transmission timing for transmitting the still image has not yet arrived (N), the process proceeds to the first step S1, and the operation after step S1 is repeatedly executed, while the transmission timing for transmitting the still image is transmitted. When it is determined that it has arrived (Y), the process proceeds to the next step S10.

  Next, in step S10, when one still image compressed image signal is stored in the second buffer memory 8, the control unit 11 equally divides the stored still image compressed image signal, for example, 12 or the like. Each of the divided 12 parts is assigned to one frame and read out one frame at a time, and the read compressed image signal for still image is supplied to the compressed image signal combining unit 9 as still image data. The short-range wireless communication module 10 converts the frequency of the obtained image data into a high-frequency signal and transmits it as a wireless signal from the transmission / reception antenna 10 (1).

  Next, in step S <b> 11, the control unit 11 determines whether or not the still image compressed image signal that is equally divided remains in the second buffer memory 8 without being read out. When it is determined that the still image compressed image signal still remains in the second buffer memory 8 (Y), the process returns to the previous step S9, and the operations after the step S9 are repeated, while the second buffer memory 8 When it is determined that the still image compressed image signal does not remain in the buffer memory 8 (N), the process proceeds to the next step S12.

  In step S12, the control unit 11 determines whether there is no image data to be transmitted as a wireless signal. When it is determined that the image data to be transmitted as a radio signal has not been lost (N), the process proceeds to the first step S1, and the operations after step S1 are repeatedly executed, while the image data to be transmitted as a radio signal is When it is determined that there is no more (Y), this series of operations is terminated.

  Next, the operation of the image data receiving apparatus 13 according to this embodiment will be described with reference to the flowchart shown in FIG.

  First, in step S21, the control unit 24 receives a wireless signal in the short-range wireless communication module 14, and reproduces and acquires a compressed image signal from the received wireless signal.

  Next, in step S22, the control unit 24 determines whether or not the compressed image signal acquired by the short-range wireless communication module 14 is a still image compressed image signal. When it is determined that the compressed image signal is not a still image compressed image signal (N), the process proceeds to the next step S23, while when it is determined that the compressed image signal is a still image compressed image signal (Y). Shifts to another step S28.

  Next, in step S23, the control unit 24 determines that the compressed image signal is a moving image compressed image signal, and therefore supplies the moving image compressed image signal to the first buffer memory 16 through the compressed image signal distributor 15. Remember there.

  Subsequently, in step S24, when a predetermined amount of the compressed image signal for moving image is stored in the first buffer memory 16, the control unit 24 reads the stored compressed image signal for moving image and reads the read compressed image signal for moving image. The low-resolution decoder 18 is supplied to restore the moving image compressed image signal to the original moving image signal.

  Subsequently, in step S25, the control unit 24 transfers the moving image signal restored by the low resolution decoder 18 to the first memory 20 and stores it therein.

  Next, in step S26, when the moving image signal stored in the first memory 20 reaches a predetermined amount, the control unit 24 reads the stored moving image signal, and the read moving image signal is the image signal selecting unit 22. And supplied to the display unit 23 as moving image data.

  Next, in step S27, the control unit 24 causes the display unit 23 to display the moving image based on the supplied moving image image data.

  On the other hand, in step S28, the control unit 24 determines that the compressed image signal is a still image compressed image signal, and supplies the still image compressed image signal to the second buffer memory 17 through the compressed image signal distributor 15. And memorize it there.

  Next, in step S29, the control unit 24 determines whether or not the still image compressed image signal stored in the second buffer memory 17 has reached one still image before being equally divided. When it is determined that the still image compressed image signal stored in the second buffer memory 17 has reached one still image (Y), the process proceeds to the next step S30, while the second buffer memory 17 When it is determined that the still image compressed image signal stored in (1) has not yet reached one still image (N), the process returns to the first step S21, and the operations after step S21 are repeated.

  Next, in step S30, when the still image compressed image signal for one still image is stored in the second buffer memory 17, the control unit 24 reads and reads the stored still image compressed image signal. The still image compressed image signal is supplied to the high resolution decoder 19, and the still image compressed image signal is restored to the original still image signal.

  In step S31, the control unit 24 transfers the still image signal restored by the high resolution decoder 19 to the second memory 21 and stores it therein.

  Subsequently, in step S <b> 32, the control unit 24 determines whether it is time to display a still image on the display unit 23. When it is determined that the timing for displaying a still image has arrived (Y), the process proceeds to the next step S33, while when it is determined that the timing for displaying a still image has not yet arrived (N) Step S32 is repeatedly executed.

  Next, in step S33, since the timing for displaying the still image has arrived, the control unit 24 reads out a predetermined amount of the still image signal stored in the second memory 21, and displays the read still image signal as an image. The image data is supplied to the display unit 23 as still image data through the signal selection unit 22.

  Next, in step S34, the control unit 24 displays one still image on the display unit 23 based on the supplied still image data.

  Subsequently, in step S35, the control unit 24 determines whether or not the reception of the wireless signal including the compressed image signal is stopped. Then, when it is determined that the reception of the radio signal has not been stopped (N), the process proceeds to the first step S21, and the operation after step S21 is repeatedly executed, while it is determined that the reception of the radio signal is stopped. When (Y), this series of operations is terminated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram illustrating a configuration of a main part of an image data transmission device according to a preferred embodiment of an image data transmission system according to the present invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram illustrating a configuration of a main part of an image data receiving apparatus according to an embodiment of the image data transmission system according to the present invention. 2 is a flowchart showing an operation history of the image data transmitting apparatus shown in FIG. 1. 3 is a flowchart showing an operation history of the image data receiving device 13 shown in FIG. FIG. 3 is an image data configuration diagram showing image data transmitted as a radio signal from the image data transmission device 1. It is an outline figure showing an example of a known image data acquisition system, and showing the principal part composition.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Image data transmitter 2 Imaging part 3, 20 1st memory (memory 1)
4, 21 Second memory (memory 2)
5 Low resolution encoder 6 High resolution encoder 7, 16 First buffer memory (buffer memory 1)
8, 17 Second buffer memory (buffer memory 2)
9 Compressed image signal synthesizer 10, 14 Short-range wireless communication module (BT module)
10 (1), 14 (1) Transmission / reception antenna 11, 24 Control unit 12, 25 Operation unit 13 Image data receiving device 15 Compressed image signal distribution unit 18 Low resolution decoder 19 High resolution decoder 22 Image signal selection unit 23 Display unit

Claims (3)

The image data transmitting apparatus includes an image data transmitting apparatus that transmits a wireless signal and an image data receiving apparatus that receives and displays the wireless signal. The image data transmitting apparatus includes an imaging unit that generates image data obtained by photographing a subject, and the image data. An image data compression processing unit that generates compressed image data by encoding the image data, an image data holding unit that temporarily holds the image data and the compressed image data, and a wireless signal transmission / reception that transmits the compressed image data as a wireless signal And a control unit for controlling the operation of the image data transmitting device, wherein the image data receiving device receives the wireless signal and generates the compressed image data, and the compressed image data. An image data reproduction processing unit that decodes and reproduces the original image data, and an image that temporarily holds the compressed image data and the image data A data holding unit; a display unit that displays reproduced image data; and a control unit that controls the operation of the image data receiving device. Each signal frame is composed of moving image data followed by divided still image data. When the image data receiving device displays the image data on the display unit, the signal is converted into moving image data for each signal frame. An image data transmission system for displaying a still image obtained by constantly displaying a moving image based on the image and integrating the divided still image data for each signal frame at a constant period. The image data transmission system according to claim 1, wherein the resolution of the still image is set to be higher than the resolution of the moving image. The image data transmission system according to claim 1, wherein each of the wireless signal transmission / reception units is a short-range wireless communication module.

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