JPH07274176A - Dynamic image transmitter - Google Patents

Abstract

PURPOSE:To prevent the degradation of an image without increasing the transmitting code quantity in a transmission side by transmitting an image corrected in a reception side to a transmission side through an incoming line in the case of detecting an uncorrectable error in a reception signal at the time of bi- directional dynamic image communication less in single directional transmission code quantity. CONSTITUTION:At the time of detecting the uncorrectable error in the reception signal, the detected error is corrected in the reception side, then immediately the corrected picture data is stored in an image memory 231 and sent to an encoding part by an input switching circuit 241. In a communication path encoder 214, the corrected image data is added with the error correction code higher in redunduncy than normal condition and sent back to the transmission side together with an error correction flag. At the time of receiving the signal in the transmission side, an output switching circuit 242 is switched to the side of an image memory 211 to locally update a corresponding area in a referring picture. Thus, the error between the reference image of a decoder on the reception side and that of an encoder on the transmission is reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moving picture transmission device for compressing and coding data such as moving pictures and voices and transmitting them bidirectionally by using a wired or wireless communication path.

[0002]

2. Description of the Related Art With the spread of cellular type mobile phones, as shown in, for example, Japanese Patent Laid-Open No. 3-109891, the function of a videophone device which has conventionally used a wired circuit such as an analog telephone line or N-ISDN. It is considered that the mobile phone also has the.

In portable videophones and the like, stable signal transmission characteristics cannot be expected and correction processing for reception errors is required. Further, since the information amount of the image signal is very large, narrow band encoding of the image signal and the audio signal is indispensable in order to improve the frequency utilization efficiency.

As a high-efficiency image compression technique, hybrid coding in which motion-compensated inter-frame prediction coding and orthogonal transform such as DCT are combined is known. ITU-R
H. It is also adopted as an international standard such as 261 and ISO / IEC11172.

FIG. 6 is a block diagram showing the structure of a conventional bidirectional transmitting / receiving apparatus for moving image signals and audio signals. The input image 102 has a motion compensation difference from the data of the previous frame in the image memory 111 or the background image data in the memory, and the residual signal thereof is DCT-transformed, quantized, and multiplexed with the voice coded data. Is made. The multiplexed data is further added with an error correction code by the channel encoder 114, buffered by the transmission buffer 115 and modulated by the modulation circuit 116, and then the antenna 1 is transmitted.
Sent from 17. The output of the quantizer 107 is
After the inverse quantization and inverse DCT, motion compensation addition is performed with the reference image stored in the image memory 111, and the locally decoded image is used as the reference image for the next screen for updating the image memory 111. The image memory 111 may be composed of a frame memory capable of accumulating reproduced images of one frame or more, and may further be configured to record a background image signal and perform background prediction at the time of encoding. On the other hand, a signal received from the antenna 117 (a signal transmitted from a transmitting / receiving device (not shown) on the transmitting side.
This transmitting side is also the same as the configuration shown in FIG. 6) is demodulated by the demodulation circuit 136 and then buffered once for error detection and correction. After that, the audio data and the image data are separated and decoded in the reverse procedure of the encoding. When an uncorrectable error is detected from the image coded signal by the channel decoder 134 or the separation circuit 133, the pixel area corresponding to the data in which the error has occurred is
Correction processing as described below is added by the error correction circuit 120.

As described above, in the motion-compensated interframe predictive coding, only the difference from the previous frame is coded in order to reduce the redundancy in the time direction, so that the coded image signal of the previous frame cannot be corrected. When a possible error occurs, the error may propagate in time and cause a fatal deterioration in image quality. In order to prevent error propagation and facilitate random access, it is usually disclosed in JP-A-63-310294.
Intra-frame coded images are periodically inserted as in No. 1.

When a large error occurs on the receiving side,
For example, Japanese Patent Publication No. 2-52478 is known in which a refresh request is issued from the receiving side to the transmitting side in frame units. However, this method has problems that it causes an increase in the amount of transmission code and that the receiving side needs to temporarily stop the image. There is also a system in which a refresh request is issued from the receiving side to the transmitting side in block units as in Japanese Patent Laid-Open No. 26132/1991, but when the frequency of reception errors increases, the increase of the transmission code amount and the propagation of errors are also prevented. Becomes difficult.

There is also known a method in which the error is reduced on the receiving side by independently correcting, for example, a partial image which is missing from the surrounding information in space-time. For example, Japanese Examined Patent Publication 4-79
No. 193, the correction is made from the information of the pixels spatially adjacent to each other, or the correction is made from the information of the pixels at the spatially same position in the temporally preceding and following frames as in JP-A-4-79689. For errors in the part that defines the coding characteristics such as the quantization mode, Japanese Patent Publication No.
It has been proposed to use the information one line before in the same frame as in No. 3-22757. Further, as in Japanese Patent Laid-Open No. 2-299378, a method is known in which coded data in the same block unit is divided into a plurality of data and each of them is transmitted through a different line so as to have error resistance. However, none of these methods can completely eliminate the error due to the reception error,
Image quality deterioration is inevitable.

[0009]

As described above, the conventional moving image transmission apparatus has a drawback that it is difficult to suppress image quality deterioration due to transmission errors without increasing the transmission code amount from the transmission side. It was An object of the present invention is to provide a moving image transmission apparatus capable of suppressing image quality deterioration due to transmission errors without increasing the transmission code amount from the transmission side.

[0010]

According to the present invention, a coding means for coding a moving picture signal using a reference image, a transmitting means for transmitting the coded moving picture signal, and a coding from a transmitting side. In a moving image transmission apparatus comprising a transmitting side and a receiving side, each of which is provided with a receiving means for receiving a moving image signal and a decoding means for decoding the received encoded moving image signal, the receiving side is decoded by the decoding means. The portion modified by the moving image signal is encoded by the encoding means, and is transmitted to the transmitting side by the transmitting means, and the transmitting side decodes the received encoded signal of the corrected portion. It is characterized in that it is decoded by means and the decoded modified portion is written in the reference image.

[0011]

According to the present invention, when an uncorrectable error is detected in a received signal in a bidirectional moving image transmission apparatus when the transmission code amount in one direction (from the receiving side to the transmitting side) is small. By transmitting the image whose error has been corrected on the receiving side to the transmitting side through the uplink, it is possible to prevent image quality deterioration without increasing the transmission code amount from the transmitting side.

Here, the correction means that any receiving side can perform the same correction processing by using the error correction bit added to the transmission code. Further, the correction means that the receiving side performs its own correction processing when the correction cannot be performed even if the error correction bit is used due to the transmission distortion / error.

Information is frequently coded and transmitted from the first moving image transmitting apparatus to the second moving image transmitting apparatus, but when the second to first transmitting is small, the receiving side (second moving image) is transmitted. Even if the image corrected by the image transmission device) is transmitted to the transmission side (first moving image transmission device), the transmission efficiency from the first to the second is not affected. On the transmission side, the subsequent frame image is encoded using the corrected image from the reception side as a reference image. That is, the encoding device on the transmission side and the encoding device on the reception side have the same reference image.

[0014]

1 is a block diagram showing the configuration of a first embodiment according to the present invention. In addition to the conventional example of FIG. 6, an input image switching circuit 241 and an output image switching circuit 242 are added. During normal bidirectional communication of an image signal and an audio signal, the input image switching circuit 241 inputs the input image 202 to the encoding unit, and the output image switching circuit 2
42 outputs a normal output image 221 and
The image memory 231 is updated. As a result, the encoding and the decoding of the received signal are performed independently as in the conventional example shown in FIG.

Here, when there is no transmission of the image signal in one direction or the transmission code amount is significantly small during the bidirectional communication, an error in the received signal or a packet which cannot be corrected by the receiving side of the image signal is generated. The loss or the like is detected, the undecodable pixel region corresponding to the loss is corrected or reproduced, and the corrected image data is immediately accumulated in the image memory 231, and the input image switching circuit 241 encodes the corrected image data. Send to the department. After the image data is encoded by the encoding unit, an error correction code having a higher degree of redundancy than usual is added in the channel encoder 214 and is transmitted to the transmission side together with a flag indicating that the image is an error correction image. (The reason why the error correction code having a higher degree of redundancy than usual is added is to eliminate the occurrence of further errors in the corrected image as much as possible). Upon receiving the encoded image data including the flag indicating that the image is a corrected image, the transmitting side immediately decodes the decoded image data and switches the output image switching circuit 242 to the image memory 211 side to cause the image memory 21.
1 to update the image data of the corresponding area of the reference image. FIG. 2 is a diagram showing a timing chart of a series of operations in this embodiment. In the figure, 10 to 12 are undecodable areas due to transmission errors and packet loss. When a non-decodable area is detected, an image is generated by the error correction circuit 220 at the timing for decoding the area, and the image data is re-encoded. Reference numerals 20 to 22 are re-encoded data, and reference numerals 30 to 32 are timings for adding an error correction code having high redundancy. 40
Reference numerals 41 to 41 show timings at which the modified image transmitted from the receiving side is decoded on the transmitting side and the image memory 211 is updated. Here, reference numeral 41 indicates that the reference image is updated at the timing when the first half of the next frame is coded, but since the same update area is used for prediction during the latter half of the frame, the timing shown here is used. However, no problem will occur. By the series of processes described above, it is possible to reduce the error between the reference image of the decoder on the receiving side and the reference image of the encoder on the transmitting side.

FIG. 3 is a block diagram showing the configuration of the second embodiment according to the present invention. In this embodiment, the inverse quantizing circuit for encoding and decoding, the inverse DCT circuit, and the motion compensation circuit are shared. In this case, it is impossible to perform encoding and decoding at the same time, but bidirectional image transmission becomes possible by performing time division processing. FIG. 4 shows a timing chart during normal bidirectional image communication. However, here, it is assumed that the input image and the received image signal have vertical blanking corresponding to one frame period or more, or are images thinned out of frames. At the time of bidirectional image communication, encoding timing 50-
At 52, the reference image output switching circuit 341 connects the motion compensation circuit 312 and the difference unit 303, and the decoder input switching circuit 350 inputs the output of the quantum device 307 to the inverse quantum device 328. At this time, the error correction circuit 320 does not perform error correction. On the other hand, at the decoding timing 60 to 62 of the received signal, the reference image output switching circuit 341 causes the motion compensation circuit 312 to operate.
And the adder 337 are connected to each other, and the decoder input switching circuit inputs the output of the moving image coded data separated by the separation circuit 333 to the dequantizer 328. Here, the image memory 31
The reference image data in 1 is reserved independently for encoding and decoding.

In FIG. 5, in the same embodiment, the amount of generated code in the input images 80 to 82 on the receiving side is small, and the undecodable area 90 corresponding to the error or packet loss of the received signal corresponding to the input images 70 to 72 on the transmitting side. 9 to 92 show timing charts in the case where a modified image is reproduced on the receiving side, the modified image is re-encoded and transmitted to the transmitting side.
The re-encoded modified image is multiplexed with the coded data for the input images 80 to 82 on the reception side together with the error correction code having high redundancy, and is transmitted to the transmission side. On the transmitting side, when the corrected image corresponding to 90 to 92 receives the data multiplexed with the input image coded signal on the receiving side,
Each of the corrected image corresponding to 92 and the input image corresponding to 80 to 82 on the receiving side is decoded, the corrected image data is used to update the reference image for encoding, and the decoded image corresponding to 80 to 82 is also used. The signal is used to update and display the reference image for decoding.

As described above, according to the present invention, the modified image is encoded by using the encoding unit used during normal bidirectional communication, and is also decoded by the decoding unit used during normal bidirectional communication on the transmitting side. By doing so, it is not necessary to significantly increase the amount of hardware. Further, according to the present invention, since the reference image memory can be corrected regardless of the correction processing method on the receiving side, it is possible to increase the degree of freedom of the correction processing on the receiving side.

[0019]

According to the present invention, in the bidirectional video transmission apparatus, when an uncorrectable error or packet loss is detected in the received signal, the receiving side corrects the image and corrects the error. And locally update the contents of the reference image memory. Therefore, it is possible to prevent deterioration of image quality on the receiving side without increasing the amount of transmission code from the transmitting side.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of a first embodiment according to the present invention.

FIG. 2 is a diagram showing an operation timing chart of the first embodiment according to the present invention.

FIG. 3 is a block diagram showing the configuration of a second embodiment according to the present invention.

FIG. 4 is a diagram showing a first operation timing chart of the second embodiment according to the present invention.

FIG. 5 is a diagram showing a second operation timing chart of the second embodiment according to the present invention.

FIG. 6 is a diagram showing an example of a conventional transmitting / receiving apparatus for moving image signals and audio signals.

[Explanation of symbols]

206 ... DCT circuit 207 ... Quantizer 208, 228 ... Inverse quantizer 209, 229 ... Inverse DCT circuit 211, 231 ... Image memory (frame memory / background memory) 212, 232 ... Motion compensation circuit 213 ... Multiplexer 214 Communication channel encoder 215 Transmission buffer 216 Modulation circuit 233 Separation circuit 234 Communication channel decoder 235 Reception buffer 236 Demodulation circuit 241 Input image switching circuit 242 Output image switching circuit 341 Reference image output switching Circuit 350 ... Decoder input switching circuit

Claims (4)

[Claims] 1. A coding means for coding a moving picture signal using a reference picture, a transmitting means for transmitting the coded moving picture signal, and a receiving means for receiving the coded moving picture signal from a transmitting side. And a decoding means for decoding the received encoded moving picture signal, the moving picture transmission device comprising a transmission side and a reception side, wherein the reception side corrects the moving picture signal decoded by the decoding means. The encoded portion is encoded by the encoding means, and is transmitted to the transmission side by the transmission means, and the transmission side decodes the received encoded signal of the modified portion by the decoding means, and decodes the encoded signal. A moving image transmitting apparatus, characterized in that a corrected portion is written in the reference image. 2. The receiving side adds an error correction code having a higher degree of redundancy than the received coded video signal to the coded signal of the modified portion and transmits the coded signal to the calling side. The moving image transmission apparatus according to claim 1. 3. The receiving side uses the decoded moving image signal including the corrected portion as a reference image when decoding encoded moving image signals of a plurality of frames received thereafter. Video transmission device. 4. The moving image transmission apparatus according to claim 1, wherein the receiving side corrects a portion including an uncorrectable error in the decoded moving image signal.