KR950016366A - Video encoding and decoding device and method - Google Patents

Abstract

This video code, the Bukho makeup and its method are to improve the coding efficiency while ensuring the independence of each module when splitting a screen and performing parallel processing for high-speed signal processing. In particular, it is to process independently regardless of the connection in the boundary area between the divided screens. An encoding apparatus for this purpose includes a memory for sequentially storing quantized data in regions set for each divided module and outputting the motion compensation; In the case of motion estimation, in the case of the boundary area, separate coding processing is performed for each first predetermined block unit (8 * 8) for the case where the designated motion vector corresponds to the area of its own module and the area of another module. Estimates a block having an optimal encoding efficiency, compares the encoding efficiency of the intra-encoding process with the encoding efficiency of the estimated block, and compares the encoding efficiency of the estimated block with the second predetermined block unit (macroblock unit). A motion estimator for selecting a code and an efficiency and then outputting a signal controlling a corresponding motion vector and an encoding processing mode; And a motion compensator for compensating for motion of data output from the memory by a code output from the motion estimator, a processing mode control signal, and a motion vector signal.

Description

Video encoding and decoding device and method

Since this is an open matter, no full text was included.

5 is a block diagram of a video encoding apparatus according to the present invention.

6 is a block diagram of a video encoding apparatus according to the present invention.

7 is a flowchart of a video encoding apparatus according to the present invention.

Claims (12)

A video encoding apparatus for dividing an applied bitstream data into at least one module or more and performing discrete cosine transform and quantization in parallel for variable length encoding; A memory for restoring the quantized data to an original signal and sequentially storing the quantized data in areas set for each divided module and outputting the motion compensation; When motion estimation is performed based on the data read out from the memory and the data applied as the current frame data, when the estimation target data exists in an area other than the boundary area, the normal motion estimation is performed. Is applied to the area of the own module and the area of the other module, respectively, for each of the first predetermined block units to estimate the block having the optimal coding efficiency, and to estimate the second predetermined block. The best coding efficiency is selected by comparing the coding efficiency of the intra-encoding process and the estimated coding efficiency of the block with respect to the data to be estimated in units, and then a signal for controlling the corresponding motion vector and coding processing mode (ITR) is obtained. A motion estimator for outputting; And a motion compensator for outputting the discrete cosine transform by performing motion compensation on the data output from the memory by the coding processing mode control signal and the motion vector signal output from the motion estimator. Device. The method according to claim 1, wherein the first predetermined block unit and encoding process performed by the motion estimator are configured to detect an encoding rate by an inter scheme when the motion vector is in the own module region. Is in the other module region, the video encoding apparatus characterized in that it is made to detect the coding rate by the intra system. The video encoding apparatus according to claim 1 or 2, wherein the criterion for determining the best coding rate is that the encoded bit is the smallest. The video encoding apparatus of claim 1 or 2, wherein the first predetermined block unit is a smaller block unit than the second predetermined block unit. A video decoding apparatus for dividing encoded bit string data into at least two modules or more and performing variable length decoding and inverse quantization in parallel, inverse discrete cosine transform processing, and inverse difference pulse code modulation to restore an original signal; A memory for sequentially storing the previous frame data output by being modulated with the inverse difference pulse code in a region set for each divided module and outputting the motion compensation; An address generator for generating an address for reading the corresponding data from the memory during motion compensation by the motion vector restored during the variable length decoding; Detects the region of the motion vector, detects the encoding mode performed at the time of encoding the detected region, and controls whether or not the data output from the memory is transmitted based on the detected result to decode the reverse differential pulse code. Video encoding apparatus comprising a processing mode controller for controlling the mode. 6. The video decoding apparatus of claim 5, wherein the motion vector applied to the processing mode controller is a motion vector on a horizontal side or a vertical side according to a division criterion. A method of encoding a video signal by dividing at least two modules of bitstream data applied in a predetermined block unit by discrete cosine transform in parallel, quantizing them, and then performing variable length encoding; Restoring the discrete cosine-converted data with the original signal; A storage process of storing the data restored through the restoration process in a memory area allocated to each module; An estimation subject region detection process for detecting whether the estimation subject region corresponds to a boundary region between the modules when estimating a motion of the data stored in the frame unit by the storing process; First motion estimation process of performing normal motion estimation and outputting a signal for controlling the motion vector detected by the motion estimation and the encoding mode for each processing block when the detection target area detection process is not a boundary area. ; In the estimation subject region detection process; As a result of the detection in the estimation target region detection process, a separate encoding process is performed according to a case in which the motion vector value corresponds to a region sufficient for data of its own module and data of another module is required. A second motion estimation process of performing motion estimation to select a block having the best coding efficiency; A third motion estimation method for selecting a block having an optimal encoding efficiency by comparing the first predetermined block unit to be estimated with the encoded value obtained by intra coding and the encoded value of the block selected in the second motion estimation process. Motion estimation process; And a motion compensation process of outputting the motion vector of the selected block and the encoding mode control signal processed in the third motion estimation process to perform motion compensation on the previous frame data and output the discrete cosine transform process. Encoding Method. 8. The method of claim 7, wherein the second motion estimation process comprises performing an encoding process by an intra method when the data of the own module corresponds to a sufficient area, and an intra method when data of the other module is required. Video encoding method comprising the step of performing an encoding process. The video encoding method according to claim 7 or 8, wherein a coding scheme that is processed differently according to the case where the data of the own module is sufficient and the data of the other module is required is applied in a second predetermined block unit. 8. The video encoding method according to claim 7, wherein the best encoding efficiency is the smallest number of encoded bits. The video encoding method of claim 9, wherein the second predetermined block unit is a smaller block unit than the first predetermined block unit. A video encoder for dividing the applied bitstream data into at least two modules and performing discrete cosine transform and quantization in parallel to the variable length encoding and a bit string data encoded and applied in the video encoder to at least two modules to be changed in parallel. A video encoding and decoding apparatus having a video decoder for long decoding and inverse quantization, inverse discrete cosine transform processing, and inverse differential pulse code modulation to recover an original signal; The video encoder restores the quantized data to an original signal and sequentially stores the quantized data in areas set for each of the divided modules, and outputs them during motion compensation, and is applied as data read from the memory and current frame data. In case of motion estimation based on the data, if the estimation target data exists in a region other than the boundary region, the conventional motion 1 estimation is performed. In the case of the boundary region, the designated motion vector corresponds to the region of its own module and other modules. In the case of the region of?, Separate encoding processing is performed for each first predetermined block unit to estimate a block having an optimal encoding efficiency, and intra coding is performed on all the estimation target data in a second predetermined block unit. Compare the coding efficiencies, select the best coding efficiencies, and then apply the corresponding motion vectors. And a motion estimator for outputting a signal for controlling an encoding processing mode (ITR), and the discrete cosine transform by performing motion compensation of data output from a memory by the encoding processing mode control signal and a motion vector signal output from the motion estimator. It includes a motion compensator for outputting so that; The dynamic decoder decodes the previous frame data output by modulating the inverse difference pulse code sequentially in areas set for each divided module, and outputs a memory for compensating for motion, by the motion vector restored during the variable decoding. An address generator for generating an address for reading the corresponding data from the memory during motion compensation, detecting an area of the motion vector, and detecting an encoding mode performed at the time of encoding the detected area, from the memory based on the detected result And a processing mode controller configured to control whether or not the output data is transmitted to control a decoding processing mode when the inverse differential pulse code is modulated. ※ Note: The disclosure is based on the initial application.