KR0152027B1 - Encoder and decoder for moving vector using by differential pulse code modulation - Google Patents

Abstract

The apparatus for encoding a dynamic vector using differential pulse code modulation of the present invention provides a variable length code length of difference values between a means for calculating a dynamic vector difference value between horizontal adjacent blocks and a means for calculating a dynamic vector difference value between vertical adjacent blocks. Means for selecting a moving vector difference value in a direction having a smaller variable length, and a variable length encoding means for encoding the selected moving vector. The motion vector reporting device for decoding the encoded motion vector thus receives a variable length-decoded means of receiving the encoded motion vector data, receives the variable-length decoded data and the predetermined feedback data, and adds the original motion vector. A first delay unit for delaying a predetermined time by receiving an adding means for outputting and a dynamic vector output from the adding unit; a second delay unit for delaying the output of the first delay unit by another predetermined time; and the first delay unit and the second delay unit And a selection means for receiving one output and selecting one of the inputs of the first delayer and the second delayer according to a predetermined selection signal synchronized with the variable-length decoded data and outputting the input to the adding means. Therefore, by encoding the dynamic vector difference value in the direction where the amount of data is small, it is possible to reduce the amount of transmitted data and to improve the data compression ratio.

Description

Poison vector encoding and decoding apparatus using differential pulse code modulation

1 is a block diagram showing a conventional motion vector encoding apparatus;

2 is a block diagram showing a conventional motion vector decoding apparatus;

3 is a block diagram showing dynamic vector coding length signals using differential pulse code modulation according to an embodiment of the present invention.

4 is a block diagram showing a dynamic vector decoding apparatus using differential pulse code modulation according to a preferred embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

31,33,44,45: delay 32,34 subtractor

35,36: code length generator 37: comparator

38,43: multiplexer 39: variable-length coding unit

100,200: vector difference calculation means 300: data selection means

41 variable length decoding unit 42: adder

The present invention relates to a motion vector encoding and decoding apparatus using differential pulse code modulation (DPCM), and in particular to differential the motion vector of the current block by using the motion vector of blocks adjacent to the horizontal and vertical directions. The present invention relates to an encoding / decoding device for pulse code modulation.

Compared to audio signals, video signal data generally have a large amount of information. Therefore, a data compression method for efficient data transfer and recording is widely used.

High-Efficient Coding techniques, which have a large compression effect by signal bands, include predictive encoding, transform encoding, and vector quantization.

Among the parts obtained by predictive encoding, there is a dynamic vector generated by image motion estimation between adjacent frames. The kinematic vector indicates, as is well known, that a given block of the current frame has the highest data correlation with which block of the previous frame.

When one video frame is divided into M video blocks horizontally and N video columns vertically, M × N motion vectors are generated per video frame by motion estimation. In order to further compress the length of data of the motion vector, the motion vector of a given block is differential pulse coded modulation (hereinafter referred to as DPCM) using the motion vector of another block existing in the same frame.

In the following description, when DPCM, the block of the current frame corresponding to the motion vector is defined as the current block.

A conventional motion vector encoding and decoding using DPCM will be described with reference to FIGS. 1 and 2. FIG. 1 is a conventional motion vector coding apparatus using DPCM, and FIG. 2 is a decoding apparatus corresponding to the coding apparatus of FIG.

The motion vectors corresponding to each of the horizontally adjacent blocks in the image frame are simultaneously input to the subtractor 13 and the delayer 11. The subtractor 13 subtracts the motion vector delayed by the motion vector input period by the delayer 11 from the motion vector of the current block to be input. Accordingly, the subtractor 13 outputs DPCM data using the motion vector of the current block and the motion vector of the block adjacent in the horizontal direction to the current block. The vector difference value output from the subtractor 13 is converted into data encoded by the variable length encoding unit 15 and output.

When the output data from the variable length coding unit 15 in FIG. 1 is input to the variable length decoding unit 21, the variable length decoding unit 21 variably decodes the input data and outputs it. The adder 23 adds and outputs the variable length decoded data and the data from the delay unit 25.

Data output from the adder 23 is applied to signal processing units such as a delay unit 25 and an inverse quantization unit.

The delay unit 25 delays and outputs the input data at the same time interval as the delay unit 11 of FIG.

As a result, the data output from the adder 23 becomes a dynamic vector before DPCM. In the above-described conventional motion vector encoding apparatus using DPCM, the DPCM and the variable are increased when the difference value of the motion vector of adjacent blocks is increased by DPCM the motion vector of the handy block using only the motion vector corresponding to one block adjacent to the current block. The amount of data being encoded is increased. Therefore, there is a problem that the data compression ratio for the same vector is lowered.

Accordingly, an object of the present invention is to DPCM using the dynamic vector of the block adjacent to the horizontal direction and the vertical direction and the vector difference value is relatively small in order to solve the above-mentioned problems, DPCM can improve the data compression efficiency An object of the present invention is to provide a dynamic vector encoding apparatus using differential pulse code modulation.

In order to achieve the above object, a feature of the present invention is a device for differential pulse code modulation of a motion vector of a current block using motion vectors generated for each motion estimation block by motion estimation. First vector difference calculating means for receiving a motion vector of a block adjacent to the current block in a horizontal direction and calculating a first vector difference value that is a difference between the motion vectors, a block perpendicular to the motion vector between the current block and the current block; Second vector difference calculation means for calculating a second vector difference value that is a difference between the motion vectors, and generating a length of a variable length code corresponding to the motion vector difference values supplied from the vector difference calculation means, respectively. And a selection control signal for comparing the magnitudes of the variable length code lengths and selecting an output of one of the vector difference calculating means according to the result. Variable means for selecting and outputting data generated from the first vector difference calculating means and the second vector difference calculating means in accordance with the selection control signal, and a dynamic vector output from the selecting means. There is a same vector encoding means including means for encoding.

According to another aspect of the present invention, there is provided a dynamic vector decoding apparatus for decoding an encoded dynamic vector, comprising: means for variable length decoding of encoded dynamic vector data, and the variable length decoded data; An adder for receiving the summed feedback data and summing and outputting the original motion vector; a first delay for receiving a motion vector output from the addition means for a predetermined time delay and delaying the output of the first delayer for another predetermined time; And selecting one of the inputs of the first delayer and the second delayer according to a predetermined selection signal synchronized with the variable long-decoded data by receiving the second delayer and the outputs of the first delayer and the second delayer. And a selecting means for outputting to said adding means.

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

3 is a block diagram showing a motion vector encoding apparatus implementing the present invention. In FIG. 3, the first vector difference calculating means 100 is configured to generate a first vector difference value between adjacent blocks in the horizontal direction. The second vector difference calculating means 200 is configured to generate a second vector difference value between adjacent blocks in the vertical direction. The data selecting means 300 is connected to the signal output terminal of the vector difference calculating means 100, 200 to receive the same vector difference values and generate a selection control signal. The multiplexer 38 is connected to the signal output terminal of the vector difference calculating means 100 and 200. The output terminal of the multiplexer 38 is connected to the variable length encoder 39.

The first vector difference calculating means 100 is supplied with the first vector 31 delaying the inputted copper vector and the same vector outputted from the first vector 31 and the first delayed delay 31. It has a first subtractor 32 connected. The second vector difference calculating means 200 includes the second vector 33 and the second delay unit 33, which are input from the second delay unit 33 and the input terminal 20 connected to the signal output terminal of the first delay unit 31. And a second subtractor 34 connected to receive the copper vector outputted from 33). The data selecting means 300 may include a first code length upper part 35 connected to receive the output signal of the first subtracter 32 and a second code length generating part connected to receive the output signal of the second subtractor 34. 36) and a comparator 37 for comparing the output signals of the code length generators 35 and 36. The signal output terminal of the comparator 37 is connected to the selection control signal input terminal s of the multiplexer 38. The above code length generators 35 and 36 have a form of a ROM for variable length encoding in response to an input signal. One frame consists of M × N blocks. Since each block has a corresponding motion vector, the motion vector is generated M horizontally and N vertically in one frame. If the kinematic vectors for the M blocks in one line occur, the kinematic vectors for the M blocks in the next line occur.

The motion vector of the current block having a period of T is input to the first vector difference calculating means 100 through the input terminal 20. The first delay unit 31 delays the input dynamic vector by T clocks. The first subtractor 32 subtracts the previous input dynamic vector T-delayed by the delay unit 31 from the current input dynamic vector to obtain a first vector difference value VD ₁ of two dynamic vectors adjacent in the horizontal direction. The motion vector output from the first delay unit 31 is delayed by (M-1) x T clocks by the second delay unit 33. Accordingly, the second delay unit 33 outputs the motion vector corresponding to the previous block vertically adjacent to the current block corresponding to the motion vector input through the current input terminal 20.

The second subtractor 34 subtracts the dynamic vector delayed by M × T from the current input dynamic vector by the second delay unit 33 to obtain a second vector difference value VD ₂ . The vector difference values VD ₁ and VD ₂ are input to the multiplexer 38 and the code length generators 35 and 36. The first code length generation unit 35 outputs the length of the variable length code of the first vector difference value VD ₁ , and the second length protection unit 36 has a second vector difference value VD ₂ . Output the length of.

The comparator 37 compares the length of data input to the first input terminal a and the data input to the second input terminal b. By comparing the data lengths, the comparator 37 selects the first input terminal IN ₁ of the multiplexer 38 when the length of the variable length code of the horizontal vector difference value is shorter than the length of the variable length code of the vertical vector difference value. To generate a control signal. On the other hand, when the length of the variable length code of the horizontal vector difference value is longer than the length of the variable length code of the vertical vector difference value, a control signal for selecting the second input terminal IN ₀ of the multiplexer 38 is generated. The multiplexer 38 outputs data selected by the selection control signal of the data selecting means 300 from among the data supplied from the first vector difference calculating means 100 and the second vector difference calculating means 200, respectively. The variable length coding unit 39 performs variable length coding on the input data and outputs it.

4 is a block diagram of an apparatus for decoding DPCM and variable length coded data by the encoding apparatus of FIG.

In FIG. 4, the variable length decoding unit 41 is a means for decoding the data encoded by the variable length encoding unit 39 in FIG. The data decoded by the variable length decoding unit 41 is supplied to the adder 42. The adder 42 outputs a motion vector used for motion compensation. The first delay 44, which is connected to receive the output signal of the adder 42, delays the input signal by a time T. The second delay unit 45 connected to the first delay unit 44 delays the input signal by (M-1) x T clocks and outputs the delayed signal. The output terminal of the first delay unit 44 is connected to the first input terminal IN ₁ of the multiplexer 43, and the output terminal of the second delay unit 45 is connected to the second input terminal IN ₀ of the multiplexer 43. do. The multiplexer 43 is supplied with a selection signal generated by the data selection means 300 of FIG. The selection signal supplied to the multiplexer 43 is synchronized to reverse DPCM the DPCM data. Therefore, the adder 42 receives the data selected by the multiplexer 43 and the output data of the variable length decoding unit 41 to generate a dynamic vector before DPCM.

As described above, the present invention compares the DPCM data compression method with the general horizontal DPCM data compression method by DPCM the motion vectors in two directions, horizontally and vertically, and performs variable length encoding / decoding for the direction in which the variable length encoded data amount is small. It has the effect of reducing the amount of data transferred.

Claims (7)

A device for differential pulse modulation of a motion vector of a current block using motion vectors generated for each motion estimation block by motion estimation, the motion vector of a current block and a motion vector of a block horizontally adjacent to the current block First vector difference calculating means for receiving an input and calculating a first vector difference value that is a difference between the same vectors; Second vector difference calculation means for calculating a second vector difference value that is a difference between the motion vectors by receiving a motion vector between the current blocks and a motion vector of a block vertically adjacent to the current block; Generate a length of a variable length code corresponding to the same vector difference values supplied from the vector difference calculation means, compare the lengths of the variable length codes, and select an output of one of the vector difference calculation means according to the result Data selecting means for generating a selection control signal for activating; Selecting means for selectively outputting two data respectively inputted from the first vector difference calculating means and the second vector difference calculating means according to the selection control signal; And a means for variable-length encoding the motion vector output from the selecting means. 2. The method of claim 1, wherein the first vector difference calculating means subtracts a difference between the first vector delaying the input dynamic vector by a predetermined time and a current vector output from the first delay vector. The vector encoding means according to claim 1, characterized by comprising a first subtractor for calculating. The motion vector of claim 1, wherein the second vector difference calculating means comprises: a second vector delaying the motion vector output through the first delay for another predetermined time and a motion vector output from the current delay vector from the current motion vector being input; And a second subtractor which calculates a difference between the same vectors by subtracting from the same. 4. The motion vector encoding means according to claim 3, wherein the second delay unit delays the motion vector of a predetermined block until the motion vector of a block vertically adjacent to the motion vector is applied to the second subtractor. The method of claim 1, wherein the data selecting means receives the first vector difference value and outputs a length of a corresponding variable length code and a length of a corresponding variable length code by receiving the second vector difference value. And a comparator for inputting a second code length generator for outputting a variable length and a variable length code data from the code length generators to compare data amounts. CLAIMS 1. A motion vector decoding apparatus for decoding an encoded motion vector, comprising: means for receiving a variable length decoding for receiving encoded motion vector data; Adding means for receiving the sum of the variable-length decoded data and the predetermined feedback data and adding the sum; A first delay unit which receives a dynamic vector output from the adding unit and delays the predetermined time; A second delayer for delaying the output of the first delayer by another predetermined time; And receiving one of the outputs of the first delayer and the second delayer and selecting one of the inputs of the first delayer and the second delayer according to a predetermined selection signal synchronized with the variable-length-decoded data and outputting the input to the adding means. The vector decoding apparatus comprising a selection means. 7. The method of claim 6, wherein the second delayer delays the motion vector output from the first delayer by a predetermined time when MxN motion vectors occur horizontally and vertically per frame for decoding the moving image data. Camcorder decoding apparatus.