RU169308U1 - Device for operative restoration of video signal of RGB-model - Google Patents

Abstract

The utility model relates to the field of digital computing and is intended for encoding a video signal when transmitting over long distances. The technical task of the utility model is to restore the data stream of the RGB model in real time after compression of the transmitted data due to recovery by supplementing the compressed binary RGB code.

Description

The utility model relates to the field of digital computing and is intended for encoding a video signal when transmitting over long distances.

A well-known element of a homogeneous environment, including an input signal processing unit, an endpoint attribute storage unit, an output logic unit, a trace recording trigger, a current location estimation unit, an information transmission unit, inputs, outputs, a control input, information inputs, information outputs, an indicator output ( AS 1291957 USSR class G 06 F 7/00, publ. 02.23.87, BI No. 7).

The disadvantage of this element is the narrow scope, due to the lack of funds for data recovery.

Closest to the proposed device in technical essence is a device for evaluating the placement of elements, containing a matrix of elements of a homogeneous medium, consisting of elements of a homogeneous medium, units for counting units, a block for finding the maximum, a first adder, a memory block, an input entry for the original hypergraph, an input for managing column permutation , line swap control input, write control input to the memory unit, current location estimation outputs, information output and installation input (AS 1430949 USSR, class G 06 F 7/00, 15/2 0, publ. 15.10.88, BI No. 38).

The disadvantage of this device is a narrow scope, due to the lack of funds for online data recovery.

The technical task of the utility model is to restore the data stream of the RGB model in real time after compression of the transmitted data due to recovery by supplementing the compressed binary RGB code.

The technical problem is solved in that in the device for the prompt restoration of the video signal of the RGB model, containing a matrix of m rows and n columns of elements of a homogeneous medium, a first maximum finding unit, an adder, a memory block, n units of counting units, and the inputs of control the permutation of the columns of the matrix of elements a homogeneous medium connected to the input of the control permutation of the columns of the device, inputs of the control of the permutation of the rows of the matrix elements of a homogeneous medium connected to the input of the control of the permutation of the rows , the inputs of the installation of the matrix of elements of a homogeneous medium are connected to the input of the installation of the device, the information inputs of the matrix of elements of a homogeneous medium are connected to the input of the matrix of electric circuits of the device, the indicator outputs of the elements of the jth column (j = 1,2, ..., n) of the matrix of elements of a homogeneous medium connected to the input of the j-th unit unit, the output of which is connected to the j-th input of the first block to find the maximum and the j-th input of the adder, the outputs of which are connected to the outputs of the maximum length of the ribs and the total length of the edges of the devices and accordingly, the recording control input of the memory block is connected to the recording control input of the device, the information outputs of the i-th row elements (i = 1,2, ..., m) of the matrix elements of a homogeneous medium are connected to the i-th information input of the memory block, the output of which is connected with the information output of the device, an additional data processing unit was introduced, containing three eight-bit registers - RG1, RG2 and RG3, respectively, one twelve-bit register - RG4, a clock generator, RS - a trigger, and two logical elements And, the first in the stroke of the pulse generator is connected to dividers, the output of the first of which is connected to the S-input of the trigger, and the output of the second to the R-input of the same trigger, the first output of the RS-trigger is connected to the second input of the first element And, and the first input of this element is connected so the same as the first input of the second element And, with the output of the second clock generator, the output of the first element And is connected to the inputs C of three eight-bit registers RG1 - RG3, and the output of the second element is connected to the input C of the twelve-bit register RG4, inputs 0-3 of the register RG1 are connected about 0-3 outputs the register RG4, 0-3 RG2 register inputs are connected to outputs 4-7 RG4 register, and inputs the register 0-3 RG3 are connected to the outputs of registers 8-11 RG4.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows a functional diagram of a device for operational recovery of the video signal of the RGB model.

General features of the invention are as follows.

The proposed device can be used in the field of telecommunications, for example, in corporate video conferencing and allows decoding of the video signal in real time.

The original task is represented as a binary-encoded RGB video signal compressed by truncating the four least significant bits of each of the three octets, 12 bits long (4 bits for each component of the truncated RGB code), FIG. 2 explains the essence of the input data, the data processing algorithm and the characteristic of the output data.

The device for operative video signal recovery of the RGB model contains a matrix 1 of m rows and n columns of elements of a homogeneous medium, a memory unit 5, installation inputs of the matrix 1 of elements of a homogeneous medium are connected to the device installation input 13, the recording control input of the memory unit 5 is connected to the control input 9 by recording the device, the information outputs of the elements of the i-th row (i = 1) of the matrix 1 of elements of a homogeneous medium are connected to the i-th information input of the memory unit 5, the output of which is connected to the information output of the device 12, p 14 pulses, decoder 17 lines, group 19.1, 19.2, ..., 19.m RS triggers, group 23.1, 23.2, ..., 23.m blocks of prohibition elements, group 18.1, 18.2, ..., 18.m decoders with permission input and the input 25 of the device start is connected to the input 26 of the pulse generator 14, the overflow output of the counter of 19 columns is connected to the R-inputs of the RS flip-flops group 19.1, 19.2, ..., 19.m, the overflow output of the counter of 22 columns is connected to the counting input of the counter of 21 lines the overflow output of which is connected to the device overflow output 26, the output of the counter of 21 lines is connected to the decoder input 17 lines, the outputs from the first to the mth of which are connected to the corresponding control inputs of groups 23.1, 23.2, ..., 23.m of blocks of prohibition elements, the corresponding outputs of which are connected to the corresponding inputs of the elements from the first to the nth columns of the matrix of 1 elements of a homogeneous environments, inputs of groups 23.1, 23.2, ..., 23.m of blocks of prohibition elements are connected to the corresponding outputs of group 18.1, 18.2, ..., 18.m of decoders with a permission input, the inputs of which are connected to the S-inputs of group 19.1, 19.2, ..., 19 .m RS-flip-flops, as well as additionally introduced recovery unit 24 a real-time code containing three eight-bit registers 24.1, 24.2, 24.3 - RG1, RG2 and RG3, respectively, one twelve-bit register 24.4 - RG4, RS - trigger 20, and two logic elements And 26.1 and 26.2 respectively, and the first output of the pulse generator is connected with dividers 21.1 and 21.2, the output of the first of which is connected to the S-input of the RS-trigger 20, and the output of the second to the R-input of the same trigger, the first output of the RS-trigger 20 is connected to the second input 26.1 of the And element, and the first input of this of the element is connected in the same way as the first input 26.2 of the AND element, with the output of the generator and clock pulses, the output 26.1 of the AND element is connected to the inputs C of three eight-bit registers 24.1, 24.1, 24.3, and the output of the second element is connected to the input C of the twelve-bit register 24.4, the outputs of the registers 24.1, 24.1, 24.3 are connected to the corresponding inputs of the RS-triggers of group 21.1, 21.2, ..., 21.m, inputs 0-3 of register 24.1 are connected to outputs 0-3 of register 24.4, inputs 0-3 of register 24.2 are connected to outputs 4-7 of register 24.4, and inputs 0-3 of register 24.3 are connected to outputs 8- 11 registers 24.4.

The purpose of the elements and blocks of the device for operational compression of the video signal of the RGB model (Fig. 1) is as follows:

Matrix 1 of elements of a homogeneous environment is intended for storing color sets (palettes) in RGB-code.

Block 5 memory is designed to store output data.

The input 6 of the recording device is used to record a matrix representing a binary code for recovery.

The input 9 of the recording control device is necessary for receiving a signal "Record" from the WUU. By this signal, the current code from block 24 is entered into the memory block 5.

The pulse generator 14 is designed to generate clock pulses that synchronize the operation of the block 24 recovery code in real time.

The counter 21 lines is used to store information about the number of the current processed row of the matrix 1.

The counter 22 columns is designed to store information about the number of the processed column in this selected row of matrix 1.

The group of 19.1, 19.2, ..., 19.m RS-flip-flops temporarily stores information about the availability of data in the memory module. The number of the selected line is set by the counter of 21 lines.

Group 23.1, 23.2, ..., 23.m of blocks of prohibition elements is necessary to block the entry of values into elements from the first to the mth rows of matrix 1 elements of a homogeneous environment from the corresponding elements of group 18.1, 18.2, ..., 18.m of decoders, respectively.

The real-time code recovery unit 24 is designed to restore the input data stream by supplementing the four high-order bits of each octet of the RGB code

The input 25 of the launch device is used to start the generator 14 pulses.

The output 27 of the overflow of the device serves to supply information about the overflow of the counter 21 lines and at the same time the completion of the block 24 recovery code in real time.

The work of blocks 1 and 5 is described in detail in the prototype and therefore is not considered here.

The proposed device is designed for online video signal recovery of the RGB model in real time.

The operation of the device for operational compression of the video signal of the RGB model consists of the following steps. Initially, the matrix 1 of the elements of a homogeneous medium contains the source binary RGB code to be evaluated. The counter of 21 lines stores the unit code ("0 ... 01"). This code is fed to the input of the decoder of 17 lines, and a single pulse appears at its first output, which goes to the control inputs of the control line 23.1, 23.2, ..., 23.m of the block of inhibit elements and allows the passage of signals from the indicator outputs of the first row of matrix 1. These the signals pass through the elements of the first 23.1 block of the ban elements and go to the inputs of the group 18.1, 18.2, ..., 18.m of the decoders with the permission input. Having passed through the decoders, the signals are sent to the S-inputs of the group of RS-flip-flops 19.1, 19.2, ..., 19.m and set the corresponding triggers to single states, provided that there are single signals. The counter of 22 columns stores the unit code ("0 ... 01").

Real-time video compression of the RGB model in real time is solved in the proposed device as follows. After recording the next “truncated” binary RGB code, the signals corresponding to this code appear on the indicator outputs of the elements of the matrix 1. At the same time, the pulse generator 14 is started and the operation of the real-time code recovery unit 24 starts.

The clock pulse from the output of the generator 14 pulses is supplied to the counting input of the counter 22, to the inputs of the half-wave dividers 21.1 and 21.2 and to the inputs of the logic elements And 26.1 and 26.2 and on the rising edge increases the contents of the counter 22 by one, at the same time the signal passing through the rising edge through a divider 21.1 it gets to the input R of the RS-flip-flop 20, at the output of which one is formed and goes to the input of the logical element And 26.1, thus, at the output of this element a single signal is generated, which is fed to the synchronization input register 24.4 and recovery code unit 24 in real time and allows him to record the values from an external source. Then, according to the decay of the pulse formed by the pulse generator 14, a signal is generated at the output of the second half-wave divider 21.2, which is fed to the input S of the RS-flip-flop 20, at the inverse output of which a single signal is generated and fed to the input of the AND gate 26.2, the output of which as a result conducting a conjunction of this value with a positive pulse of the clock generator 14, a single signal appears, which is fed to the synchronization inputs of the registers 24.1, 24.2 and 24.3 of the real-time code recovery unit 24, thereby allowing them to write values stored on the corresponding outputs of the register 24.4.

The next clock pulse from the generator 14 pulses is fed to the counting input of the counter 22, to the inputs of the half-wave dividers 21.1 and 21.2 and to the inputs of the logic elements And 26.1 and 26.2 and on the rising edge increases the contents of the counter 22 by one, at the same time the signal passing along the rising edge through a divider 21.1 it gets to the input R of the RS-flip-flop 20, at the output of which one is formed and goes to the input of the logical element And 26.1, thus, at the output of this element a single signal is generated, which is fed to the synchronization input reg 24.4 Stra recovery code unit 24 in real time and allows him to record the values from an external source. Then, according to the decay of the pulse formed by the pulse generator 14, a signal is generated at the output of the second half-wave divider 21.2, which is fed to the input S of the RS-flip-flop 20, at the inverse output of which a single signal is generated and fed to the input of the AND gate 26.2, the output of which as a result conducting conjunction of this value with a positive pulse of the generator 14 clock pulses, a single signal appears, which receives the synchronization inputs of the registers 24.1, 24.2 and 24.3 of the block 24 recovery code in real time, however By allowing them to write the values stored in the corresponding outputs of the register 24, and at the outputs of the registers 24.1, 24.2 and 24.3 of the real-time code recovery unit 24, the result of the previous code recovery is already found.

Thus, the proposed device for the operational recovery of the video signal of the RGB model provides the ability to quickly restore the video signal of the RGB model. This ensures the expansion of the functionality of the device and, therefore, the field of its appropriate application.

Claims (1)

The device for operative video signal recovery of the RGB model contains a matrix (1) of m rows and n columns of elements of a homogeneous medium, a memory block (5), installation inputs of a matrix (1) of elements of a homogeneous environment are connected to the device installation input (13), the recording control input of the memory unit (5) is connected to the device recording control input (9), the information outputs of the i-th row elements (i = 1) of the matrix (1) of elements of a homogeneous medium are connected to the i-th information input of the memory block (5), the output of which is connected with information output (12) of the device , pulse generator (14), line decoder (17), group (19.1, 19.2, ..., 19.m) of RS-flip-flops, group (23.1, 23.2, ..., 23.m) of prohibition elements blocks, group (18.1, 18.2 , ..., 18.m) decoders, and the input (26) of the device start is connected to the input of the pulse generator (14), the overflow output of the counter (22) of the columns is connected to the R-inputs of the group (19.1, 19.2, ..., 19.m) RS -triggers, the overflow output of the counter (22) of the columns is connected to the counting input of the counter (21) of the lines, the overflow output of which is connected to the output (25) of the overflow of the device, the output of the counter (21) of the lines is connected to the decoder input a torus (17) of rows whose outputs from the first to the mth are connected to the corresponding control inputs of the groups (23.1, 23.2, ..., 23.m) of the blocks of prohibition elements, the corresponding outputs of which are connected to the corresponding inputs of the elements from the first to the nth columns matrices (1) of elements of a homogeneous environment, the inputs of the groups (23.1, 23.2, ..., 23.m) of the blocks of prohibition elements are connected to the corresponding outputs of the group (18.1, 18.2, ..., 18.m) of decoders with a permission input, the inputs of which are connected to S -inputs of the group (19.1, 19.2, ..., 19.m) of RS-flip-flops, as well as an additional block (24) is restored real-time code containing three eight-bit registers (24.1, 24.2, 24.3) - RG1, RG2 and RG3, respectively, one twelve-bit register (24.4) - RG4, RS - trigger (20), and two logical elements And (26.1) and (26.2), respectively, with the first output of the pulse generator (14) connected to the dividers (21.1) and (21.2), the output of the first of which is connected to the S-input of the RS-trigger (20), and the output of the second to the R-input of the same trigger, the first output of the RS-trigger (20) is connected to the second input (26.1) of the element And, and the first input of this element is connected in the same way as the first input (26.2) of the element And, with the output of the clock generator (14), the output (26.1) of the element And is connected to the inputs C of three eight-bit registers (24.1, 24.2, 24.3), and the output of the second element is connected to the input C of the twelve-bit register (24.4), the outputs of the registers (24.1 , 24.2, 24.3) are connected to the corresponding inputs of the RS-triggers of the group (19.1, 19.2, ..., 19.m), the inputs of 0-3 register (24.1) are connected to the outputs of 0-3 register (24.4), the inputs of 0-3 register ( 24.2) are connected to the outputs of the register 4-7 (24.4), and the inputs of the 0-3 register (24.3) are connected to the outputs of the 8-11 register (24.4).

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