KR100223985B1 - Video packet apparatus and method - Google Patents

Abstract

The present invention relates to a method and apparatus for implementing an H.261 packet header conversion apparatus implemented in a distributed / bridging multilateral access control apparatus of a small desktop video conference system based on H.261 on a packet network. In order to solve the problem such as the reverse of the arrival order, and to change the header information, the block group is decoded when decoding one image so that four 1/4 common intermediate format images can be combined into one common intermediate format image. Apparatus and method of video packets to be the smallest unit that can be independently decoded and displayed

Description

Video packetization apparatus and method

1A to 1C are video configuration diagrams of 1/4 common intermediate format, common intermediate format, and super common intermediate format, respectively.

2A is a diagram of the first block group video packet of a picture.

2B is a diagram of the remaining block group video packets of one picture.

3 is a diagram of a decentralized / bridging multiparty connection control device.

4 is a process flow diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: Packet Header 2: Picture Start Code

3: Temporary standard 4: Picture type

5: Group of Block Start Code

6: Block Group Number

The present invention relates to a H.261 video packetization method implemented in a distributed / bridging multipoint control unit (MCU) of a small desktop video conferencing system based on H.261 on a packet network. The present invention relates to an H.261 video packetization method that can simplify the overall structure of a distributed / bridging multi-connection controller.

In general, H.261 video decoder uses Common Intermediate Format (CIF) as its standard video. The standard image is composed of a luminance signal having a size of 352 × 288 and two color signals having a size of 176 × 144 in pixel units, and the luminance signal is divided into 12 groups of blocks (GOBs). The block group of is composed of 176 x 48 pixels.

Each block group is divided into 33 macroblocks, each of which has a size of 16 × 16 pixels, and the macroblock is divided into four sections, each of which has a size of 8 × 8 pixels. .

In general, a distributed / bridging multi-party access control apparatus displays a video signal, which is sent from a conference participant, from a terminal of each user in a compressed state or a decoded state. That is, the signal input from various video signal sources is processed into a format that can be processed through a preprocessing process and then compressed and encoded.

Therefore, when a multi-party access control device is used in a packet network, most synthesis apparatuses use a method of receiving all packets necessary for synthesis, performing synthesis, and generating the result back into one packet.

The above method has a problem in using the codec system due to causes such as transmission delay existing in the packet network and reversal of the packet arrival order. Also, when packetizing a video stream and transmitting the packet, the unit of packetization is determined. It is difficult to load all the information necessary for decoding a single image in one packet, and when the information is divided into several packets, there is a problem in that real-time transmission / decoding becomes difficult.

An object of the present invention is to implement an efficient packetization technique by finding a packetization unit of a video stream at an appropriate level in a multilateral access control apparatus used on a packet network to solve the above problem.

In order to achieve the above object, the present invention comprises the steps of determining whether the data is smaller than 16 bits by inputting an H.261 bitstream from the encoder and setting the flag to 0 to start the picture start code and search for the next 16 bits. And, if the data is smaller than 16 bits, shift all packets into packets and send the packet to the transmission unit, and if the data is larger than 16 bits, determining whether the data is a block group start code. If it is not a code, shifting one bit into a packet and searching for the next 16 bits excluding the one transmitted, determining if the flag is 0 if the data is a block group start code, and if the flag is 0 Otherwise, if the flag is set to 0 and the configured H.261 video packet is sent to the transmitting unit, the next 16-bit retrieval process is repeated. If the flag is 0, 16 bits are shifted and sent as a packet, and then the block group number is searched to determine whether the block group number is 0. If the block group number is 0, the block group number is 4 bits. And repeating the next 16-bit search process after sending the packet to the packet, and if the block group number is not 0, shifting the 4 bits by sending the packet with a flag of 1 and repeating the next 16-bit search process. Characterized in that.

The flag is used to control that only one block group header is included in the same packet.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1A to 1C are video configuration diagrams of a 1/4 common intermediate format (QCIF), a common intermediate format (CIF), and a super common intermediate format (SCIF), respectively. 3, common intermediate formats are block groups 1 to 12, block groups 1, 3, and 5 are 1/4 common intermediate format 1 area, and block groups 2, 4 and 6 are 1/4 common intermediate format 2 area, block group 7 , 9, 11 are three quarter common intermediate formats, and block groups 8, 10, and 12 are four quarter common intermediate formats. Here, block group 1 is an image header and block group 1 having general information necessary for decoding a picture layer, which is a unit including complete image information of one scene, and super common intermediate format is 4 times of common intermediate format. It consists of four.

2A is a diagram of a first block group video packet of a picture, comprising a packet header 1 which is a fixed length header of a particular packet, a picture start code 2 consisting of 20 bits indicating that a picture starts, and 32 possible A temporary reference section 3 consisting of 5 bits formed by increasing the value in the previously transmitted image header by adding 1 to the number of non-transmitted images since the last transmission, and 4 The first bit is 0, the minimum common intermediate format. If the first bit is 0, a picture type (4) of 6 bits, which is information about a complete picture, which is a common intermediate format, and a block group start code of 16 bits indicating that one block group starts (5). ) And a block group number 6 which is 4 bits representing the position of the block group in one image.

2B is a diagram of the remaining block group video packets of one picture, including a packet header 1 which is a fixed length header of a specific packet, a block group start code 5 indicating that one block group starts, and one picture It consists of a block group number 6 indicating the position of the block group.

3 is a diagram of a distributed / bridging multi-party connection control device, which is a temporary storage device used for correcting when information is flowing at different speeds or when information is generated when transferring information from one device to another. The receiver buffer 7 determines the display position of the current packet by referring to a packet header filter 8 for extracting or removing information necessary for decoding the image layer, a packet header which is a fixed length header of a specific packet, and a connection information table. The control unit 9 extracts a value necessary for converting the H.261 header pack appropriately, and the H.261 header conversion unit 11 performs H.261 header conversion using the information provided by the control unit. The H.261 decoder 12 which receives the encoded signal transmitted in the packet and finds the original information signal, and when a signal is applied to the input terminal, the signal is output to a specific output terminal. Via the packetization unit 14 at the H.261 encoder (13) for generating is configured as a transmission unit 15 for sending data.

4 is a process flow diagram of the present invention, in which an H.261 bitstream is input from an encoder (101) and a flag is set to 0 (102), an image start code is started and the next 16 bits are retrieved (103) so that data is 16 bits. If it is smaller (104), it shifts all of the packets to send a packet to the transmitter (105) and ends (106). If the data is larger than 16 bits, it is determined whether it is a block group start code (107). If it is not a block group start code, it shifts one bit into a packet (108), and then repeats the process of searching for the next 16 bits (103). If it is a group start code, it is determined whether the flag is 0 (109). If it is 0, 16 bits are shifted and sent to the packet (110). After searching for a block group number of 4 bits, the block group number of 4 bits is determined to be 0. If (112) is 0, 4 bits are shifted and sent to the packet (113). Then, the process of searching for the next 16 bits is repeated (103). If not 0, the flag is set to 1 (114). The process of searching for the next 16 bits is repeated (103). In addition, if the block group start code 107 and the flag is not 0, the flag is set to 0 (115), and then the H.261 video packet is sent to the transmitting unit (117).

As described above, the present invention can implement the packetization function of the H.261 video stream which is essential for the distributed / bridging multi-party controller required for the H.261-based video conferencing system implemented in the packet network. You can solve problems like reverse.

Claims (2)

Inputting the H.261 bitstream from the encoder and setting the flag to 0 to start the picture start code and search for the next 16 bits to determine whether the data is smaller than 16 bits; and if the data is smaller than 16 bits, Shifting all the packets into packets and sending the packet to the transmission unit, and completing the packet; determining whether the block group start code is greater than 16 bits; and shifting one bit into the packet if the data is not the block group start code. Search for the next 16 bits after transmission and determine if the flag is 0 if the data is a block group start code; if the flag is non-zero, send the H.261 video packet to the transmitter with the flag 0. Repeat bit search and if the flag is 0, shift 16 bits and send the packet and check the next 4 bits block group number. Determining whether the block group number is 0, and if the block group number is 0, shift the 4-bit block group number to send the packet, and then repeat the next 16-bit search process, and if the block group number is not 0, And shifting the four bits with the flag as 1 to send the packet and repeating the next 16-bit search process. A reception buffer, which is a temporary storage device used for correcting when the information flow rate is different or the timing of occurrence of information, a packet header filter for extracting or removing information necessary for decoding the image layer from the reception buffer, and the packet A control device that sends out a control signal in a timely manner with reference to the connection information table according to the header information extracted by the header filter, and can be displayed at a suitable display position through the H.261 header conversion device using the information provided by the control device. H.261 decoder that receives the coded signal transmitted in the converted packet and finds the original information signal, H.261 encoder that generates signal at specific output when signal is applied to the input terminal, and packetizer at the encoder. And a transmission unit for transmitting data.