JP2010268490A - Radio communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image playback device for temporarily storing image data whose frame rate of a motion image is 1 frame/sec or less on a reception side, of playing back the image data at the same frame rate as that when the image data is received in real time when playing back the stored image data, and of changing a playback rate. <P>SOLUTION: Read is controlled so that a reception state is also stored when storing image data transmitted in real time and the reception state is reproduced when sending the image data stored on the reception side to a decoder. By making a read rate variable, the playback rate is varied. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to an image reproducing apparatus.

In recent years, digitalization of communication has rapidly progressed, and image transmission for digitizing moving image data and performing communication via the Internet or a mobile phone line has been actively performed. The MPEG-4 (Moving Picture Experts Group 4) standard recommended by the International Organization for Standardization (ISO) has a limited image transmission speed (for example, 64 Kbit / sec or less). This is an image compression method that can be transmitted over a line.

Here, in a general MPEG system, as disclosed in Patent Document 1 and Non-Patent Document 1, the use of a time stamp enables strict timing reproduction of an image.
On the other hand, in the MPEG-4 standard, as described above, a moving image having a frame rate of 1 frame / sec or less can be transmitted so that an image can be transmitted even at a low transmission speed such as a cellular phone. In this case, the time stamp interval is 1 second or more, and in a normal MPEG system, if the time stamp interval exceeds 700 ms, it is determined that the time stamp is not continuous. , The problem that the video does not play properly. In such a case, in the image decoding apparatus, when data for one image is received without using a time stamp, the image is reproduced normally by reproducing the image.

JP 2002-176663 A Hiroshi Fujiwara / Hiroshi Yasuda, "Point Illustrated Broadband + Mobile Standard MPEG Textbook", ASCII Publishing Co., Ltd., February 2003, p.313

  In the conventional image reproducing apparatus described above, when the frame rate is 1 frame / sec or less, the image decoding apparatus reproduces an image when receiving data for one image without using a time stamp. However, this operation is limited to the case where the receiving side is receiving data in real time. In other words, when image data with a frame rate of 1 frame / sec or less is temporarily stored on the receiving side and played back, the image data is continuously sent to the image decoding device. Has a problem that it is greatly different from the case of receiving image data in real time. Naturally, in this case, since standard reproduction as a reference cannot be performed correctly, it is meaningless to change the reproduction speed.

The present invention eliminates these disadvantages, and once the image data with a frame rate of 1 frame / sec or less is stored on the receiving side and played back, it is played back at the same frame rate as when the image data was received in real time. An object of the present invention is to provide an image reproducing apparatus that can perform the change of the reproduction speed.

In order to achieve the above object, an image reproduction device according to the present invention is an image reproduction device for reproducing an image, wherein the image reproduction device includes a receiving unit that receives data and an image received by the receiving unit. When the information indicating the number of slots is output from the data and the line control device, information indicating the number of slots is added to the image data and stored, and when the number of slots is not output from the line control device, it is received. The number of slots is determined from the transmission speed of the data, and a storage unit that stores information indicating the number of slots added to the image data, and the received image data or the image data stored in the storage unit is reproduced. And the number of slots added to the image data stored in the storage unit when the storage unit reproduces the image data stored in the storage unit. It represents information identifying the speed of reading the image data from the storage unit based on, characterized by comprising a reading control section for controlling the reading speed.

Furthermore, in an image transmission system including at least a wireless transmission device that transmits image data through a wireless line and a wireless reception device that receives the image data transmitted from the wireless transmission device, the wireless reception device transmits data to In the case where information indicating the number of slots is output from the receiving unit to be received and the image data received by the receiving unit and the line control device, the information indicating the number of slots is added to and stored in the image data, and line control is performed. When the number of slots is not output from the device, the number of slots is determined from the transmission speed of the received data, and a storage unit that stores information indicating the number of slots added to the image data and the received image An image decoding unit that reproduces data or image data stored in the storage unit, and the storage unit stores the image data stored in the storage unit. A read control for specifying a speed for reading the image data from the storage unit based on information indicating the number of slots added to the image data stored in the storage unit and controlling a read speed It comprises the part.

According to the present invention, image data having a frame rate of 1 frame / sec or less is temporarily stored on the receiving side, and when this is played back, it can be played back at the same frame rate as when the image data was received in real time, You can also change the playback speed.

1 is a block diagram illustrating an example of an image reproduction device of the present invention. The system structural example at the time of the image transmission in a digital regional disaster prevention radio system. An example of a frame configuration in a digital regional disaster prevention radio system. The system structural example at the time of the image transmission in a digital broadcast communication system. An example of a frame configuration in a digital broadcast communication system.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIG. The image reproduction apparatus shown in FIG. 1 includes a receiving unit 1, a storage unit 2, a read control unit 3, an image decoding unit 4, and a switching unit 5.

First, processing for receiving and reproducing image data in real time will be described. The receiving unit 1 receives a signal (for example, a radio signal) including image data transmitted in real time, extracts image data from the signal, and outputs the extracted image data. When the image data output from the receiving unit 1 is reproduced in real time, the switching unit 5 is set to the a side and is reproduced as a moving image by the image decoding unit. The image data can be stored in the storage unit 2. At this time, the reception state is also stored in the storage unit 2 from the reception unit 1 at the same time.

Next, processing for reproducing image data stored in the storage unit 2 will be described. The control unit 3 calculates the transmission rate of the image data based on the reception state corresponding to the image data stored in the storage unit 2, and reads the image data from the storage unit 2 at the same speed as the transmission rate. Then, by switching the switching unit 5 to the b side, the moving image data stored in the storage unit 2 by the image decoding unit 4 is reproduced at the same speed as when received in real time.

Regarding the speed at which image data is read from the storage unit 2, (1) a method for changing the period for reading the fixed data amount at a fixed data amount at a time, and (2) a period for reading the data are fixed. Another possible method is to vary the amount of data read at one time. At this time, in the case of (1), it is possible to change the playback speed of moving images by making the amount of data read at a time variable, and in the case of (2), making the data read cycle variable.

Next, an embodiment of an image transmission system using the image reproduction apparatus will be described in detail with reference to FIGS.
FIG. 2 shows a system configuration example at the time of image transmission in the digital regional disaster prevention radio system. This system includes a mobile station side equipment including a camera 6, an image encoding unit 7, a mobile station radio 8, a base station radio 9, a line control device 10, an image decoding function, an image display function, a storage unit 2, and the like. It is comprised from the base station side equipment which consists of the personal computer 11 which has.

In the digital regional disaster prevention radio system shown in FIG. 2, when a disaster occurs, the mobile station moves to the disaster occurrence site and the like to take a picture of the disaster site and send the image to the base station. Specifically, an image captured by the mobile station side camera 6 is encoded by the image encoding device 7 by call connection from the mobile station side or the base station side, and the encoded image data is stored in the mobile station. It is sent to the base station radio 9 via the radio 8. The base station radio 9 sends the received image data to the personal computer 11 via the line control device 10. At this time, the personal computer 11 not only reproduces the image in real time by the image decoding unit, but also stores the image data in the storage unit 2.

FIG. 3 shows a frame configuration example of a radio signal used in the digital regional disaster prevention radio system. In this example, there are four slots of CH1 to CH4 in the basic frame, but since one slot of CH1 is used as a control channel among these, the maximum slot that can be used for data transmission is CH2-4. There are 3 slots. In this example, three uplink slots are used for image data transmission.

In this embodiment, the effective transmission rate when using 3 slots is 16.8 Kbit / sec (1 slot 5.6 Kbit / sec).
In a system that requires about 30 frames per second, such as the Television System Committee), if the encoding rate per image is 504 Kbit / sec (= 16.8 bits / sec x 30 frames) or higher, it is possible to transmit video frames that can be transmitted. The rate is 1 frame / sec or less.

When the line control device 10 outputs information on the number of slots to the personal computer 11 at the time of call connection, the personal computer 11 adds the information representing the number of slots to the storage file name of the image data and stores it. When reproducing moving image data, image data is read from the file at a transmission rate corresponding to the number of slots added to the file name and sent to the image decoding unit.

For example, if it is known from the slot number information from the line control device 10 that 3 slots are being used, the file name is stream1.bts_3slot and saved. When playing a file, the extension is bts_3slot, so it can be seen that the number of slots is 3. Therefore, the image data is read from the storage unit 2 at a reading speed of 16.8 Kbit / sec = 2100 Byte / sec, and this is decoded. Send to Kabubu.

On the other hand, if the line control device 10 does not output information on the number of slots to the personal computer 11 during call connection, the number of slots at that time is determined from the transmission speed of the received data, and this is used as a storage file name for image data. The information indicating the number of slots is added and saved. For example, from 1 slot 5.6 Kbit / sec = 700 Byte / sec, 2 slots 11.2 Kbit / sec = 1400 Byte / sec, 3 slots 16.8 Kbit / sec = 2100 Byte / sec, the transmission speed threshold is 1050 Byte / sec (hereinafter referred to as threshold 1A) ), 1750 Byte / sec (hereinafter referred to as threshold 2A). When the image data is stored for a certain period of time, if the maximum value of the transmission speed of the received data is equal to or less than the threshold value 1A, it is determined that one slot. If the maximum value of the transmission rate of received data is not less than the threshold value 1A and not more than the threshold value 2A, it is determined that there are two slots. If the maximum value of the transmission rate of received data is greater than or equal to the threshold 2A, it is determined that there are 3 slots. Using the number of slots, the personal computer 11 adds the information indicating the number of slots to the save file name and saves it. At the time of file reproduction, the image data is read from the file at the transmission speed corresponding to the information indicating the number of slots added to the file, and sent to the image decoding unit.

For example, if it is known from the maximum value of the transmission rate of received data that 3 slots are being used, the file name is saved as stream2.bts_3slot. When playing a file, the extension is bts_3slot, so it can be seen that the number of slots is 3. Therefore, the image data is read from the storage unit 2 at a reading speed of 16.8 Kbit / sec = 2100 Byte / sec, and this is decoded. Send to the conversion unit to play the image.

In this embodiment, the method of changing the playback speed of moving images by changing the reading speed is the same as that of the above-described image decoding apparatus, and thus the description thereof is omitted here.
FIG. 4 shows a system configuration example at the time of image transmission in the digital broadcast communication system. This system includes a slave station side equipment comprising a slave station radio 12, an image encoding device 13, a surveillance camera 14, and a pan head 15, a master station radio 16, an image decoding function, an image display function, and a storage unit 2.
And so on.

In the digital broadcast communication system shown in FIG. 4, a monitoring camera 14 is installed on the slave station side, and an image of the monitored location is transferred to the master station side by making a call connection from the master station side to the slave station as necessary. Sent. Specifically, an image captured by the monitoring camera 14 on the slave station side is encoded by the image encoding device 13 by call connection from the master station side, and the encoded image data is stored in the slave station radio 12. Is sent to the master station radio 16 via. The master station radio 16 sends the received image data to the personal computer 17. At this time, the personal computer 17 not only reproduces the image in real time by the image decoding unit, but also stores the image data in the storage unit 2.

FIG. 5 shows a frame configuration of the digital broadcast communication system. In the case of a digital broadcast communication system, there are 6 slots of CH1-6 in the basic frame. Of these, 1 slot of CH1 is used as a control channel, and 1 slot of CH2 is used for the pan head control of the surveillance camera. Is used, the maximum slots that can be used for data transmission are 4 slots of CH3-6. In this example, 4 uplink slots are used for image transmission.

In this example, the effective transmission rate when using 4 slots is about 25.6 Kbit / sec (when 1 slot is about 6.4 Kbit / sec), so an image of about 30 frames per second such as NTSC is required. If the encoding rate per image is 768 Kbit / sec (= 25.6 bits / sec × 30 frames) or more, the frame rate of the transmittable moving image is 1 frame / sec or less.

When the base station radio 16 outputs information on the number of slots to the personal computer 17 at the time of call connection, information indicating the number of slots is added to the storage file name of the image data and stored.

For example, if it is known from the information on the number of slots from the master station radio 16 that 4 slots are being used, the file name is saved as stream3.bts_4slot. When playing back a file, the extension is bts_4slot, which indicates that the number of slots is 4. Therefore, the image data is read from the storage unit 2 at a reading speed of 25.6 Kbit / sec = 3200 Byte / sec, and this is decoded. Send to the conversion unit to play the image.

On the other hand, if the master station radio 16 does not output information on the number of slots to the personal computer 17 during call connection, the number of slots at that time is determined from the transmission speed of the received data, and this is used to store the image data storage file. The information indicating the number of slots is added to the name and saved. 1 slot 6.4 Kbit / sec = 800 Byte / sec, 2 slot 12.8 Kbit / sec = 1600 Byte / sec, 3 slot 19.2 Kbit / sec = 2400 Byte / sec, 4 slot 25.6 Kbit / sec = 3200 Byte / sec. 1200 Byte / sec (hereinafter referred to as threshold 1B), 2000 Byte / sec (hereinafter referred to as threshold 2B), 2800 Byte / sec (hereinafter referred to as threshold 3B). When the image data is stored for a certain period of time, if the maximum value of the transmission speed of the received data is equal to or less than the threshold value 1B, it is determined as one slot. If the maximum value of the transmission rate of the received data is the threshold value 1B or more and the threshold value 2B or less, it is determined that there are two slots. If the maximum value of the transmission rate of the received data is the threshold value 2B or more and the threshold value 3B or less, it is determined that there are 3 slots. If the maximum value of the transmission rate of received data is greater than or equal to the threshold value 3B, it is determined that there are 4 slots. Using the number of slots, the personal computer 11 adds the information indicating the number of slots to the save file name and saves it.

For example, if it is known from the maximum value of the transmission rate of received data that 4 slots are being used, the file name is saved as stream4.bts_4slot. When the file is played back, the extension is bts_4slot, which indicates that the number of slots is 4. Therefore, the image data is read from the file at a transmission rate of 25.6 Kbit / sec = 3200 Byte / sec, and this is decoded. To play the image.

In this embodiment, the method of changing the playback speed of moving images by changing the reading speed is the same as that of the above-described image decoding apparatus, and thus the description thereof is omitted here.

DESCRIPTION OF SYMBOLS 1: Reception part 2: Storage part 3: Reading control part 4: Image decoding part 5: Switching part 6: Camera 7: Image coding apparatus 8: Mobile station radio | wireless machine 9: Base station Radio: 10: Line control device, 11: Personal computer, 12: Slave radio, 13: Image encoding device, 14: Surveillance camera, 15: Head, 16: Master radio, 17: Personal computer.

Claims (2)

An image playback device for playing back an image,
The image reproduction device includes a receiving unit that receives data;
When the image data received by the receiving unit and information indicating the number of slots are output from the line control device, information indicating the number of slots is added to the image data and stored, and the number of slots is determined from the line control device. If not output, a storage unit that determines the number of slots from the transmission speed of the received data, and stores information indicating the determined number of slots added to the image data;
An image decoding unit that reproduces the received image data or the image data stored in the storage unit;
When the storage unit reproduces the image data stored in the storage unit, the image data is read from the storage unit based on information indicating the number of slots added to the image data stored in the storage unit. An image reproducing apparatus comprising: a reading control unit that specifies a reading speed and controls the reading speed.
In an image transmission system including at least a wireless transmission device that transmits image data through a wireless line and a wireless reception device that receives the image data transmitted from the wireless transmission device,
The wireless receiver includes a receiving unit that receives data;
When image data received by the receiving unit and information indicating the number of slots are output from the line control device, information indicating the number of slots is added to the image data and stored, and the number of slots is determined from the line control device. If not output, a storage unit for determining the number of slots from the transmission speed of the received data, and adding and storing information representing the number of slots to the image data;
An image decoding unit that reproduces the received image data or the image data stored in the storage unit;
When the storage unit reproduces the image data stored in the storage unit, the image data is read from the storage unit based on information indicating the number of slots added to the image data stored in the storage unit. An image transmission system comprising: a reading control unit that specifies a reading speed and controls the reading speed.