RU2159507C1 - Device for information encoding and decoding, information transmission system using channel compression, system for information transmission in telecommunication network - Google Patents

Abstract

FIELD: telecommunications. SUBSTANCE: invention may be used for digital representation and transmission of data arrays through communication channels, translation of input and output formats in processor systems, encryption of messages and protection data of securities, money or cards. Devices may be used for analysis and synthesis of audio or video information, as well as in data compression systems for compressing transmission channels, for transmission of messages through telecommunication networks, including Internet. Invention ensures compatibility of computer engineering equipment, digital TV equipment, video monitors of different communication channels, possibility of displaying audio and/or sequence of digital signals as color image. Such presentation provides possibility to extend set of tools for analysis and/or synthesis of signal characteristics and/or state and/or characteristics of information sources using visual, graphical and statistical analysis tools. Goal of invention is achieved by raster encoding and/or decoding units and assemblies, which convert data into graphical files of raster data and back and are introduced into encoding and/or decoding systems, information transmission systems using channel compression and telecommunication networks. EFFECT: increased functional capabilities. 20 cl, 7 dwg

Description

 The claimed systems relate to the means of converting, storing and transmitting information using digital coding of signals and means, computers and are based on the conversion of input binary data into a raster data array, which when visualized is an image of a converted message.

 The claimed systems can be used for transferring data arrays through communication channels, matching input and output data streams in processor systems, encoding and encrypting messages, encoding security elements of securities, money, and cards. Systems can be used for analysis and synthesis of audio or visual information, also in data compression systems for compressing transmission channels. To send messages over telecommunication networks, including over the Internet.

State of the art
A known system for receiving, processing, storage, transmission and playback of images. The system comprises a television signal receiver coupled to an image memory and a controller, a decoder and a printer.

 The specified system is used for facsimile and electronic communications, the image memory stores encoded image data, the printer is designed to print data in the form of images (US 4805135 A, 02.14.89, H 04 N 1/04).

 Known systems for information exchange of data, storage and retrieval of information in a computer network, in which data over the network is moved in digital form.

 Movable data on the receiving side is restored, converted by decoding and processing into image data, images can also be recorded on optical discs (US 4817050 A, 03/28/89, G 06 K 9/00).

 A known system and method for transmitting text and graphic information between a computer and a remote display terminal. The system contains information input-output blocks connected to the processor, random access memory, control unit, interconnected via system buses. The system is designed to store, display, print and otherwise manipulate the stored color image, while the system provides encoding of the information received at the image input and decoding the image into a code signal transmitted via a communication channel to a remote terminal. The processor of the system is connected to the memory, modem, graphic card connected to the monitor. The remote display terminal comprises a processor connected to a modem designed to interface with a communication channel on one side and with memory or with a means of writing to a disk on the other side (US 5235680 A, 10.08.93, G 06 F 15/00).

 Known systems do not allow to coordinate the input and output data streams of external devices connected to information and / or computer systems by simple means.

 Known systems due to complex conversions of some formats to others have the property of losing some of the information, or the implementation of such transformations requires a lot of redundant information.

 Closest to the technical nature of the claimed system of transmitting information with compression of communication channels is an information transmission system with compression of channels containing transmitting and receiving parts. The input signals of the system are the signals of sound programs and digital data signals that are converted in codecs, for example, are encoded by an MPEG encoder to compress digital audio data. Further, all individual digital streams from all channels arriving at the inputs of the system are multiplexed by the control unit into a combined digital stream, which enters the modulator and further into the communication channel. When receiving carry out the inverse transformation. The incoming signals are demodulated in a demodulator, demultiplexed by means of a control unit, and each is sent to its own decoding unit (codec), after which it is subjected to digital-to-analog conversion and transmitted to the corresponding signal receiver (see Kovalgin, Radio Broadcasting and Electroacoustics, M., Radio and Communications, 1999 ( signed for publication 10/29/98), pp. 723-724).

 The known system does not allow transmitting signals of television channels of different standards and different resolutions on a single communication channel.

 The closest in technical essence information transmission system in a telecommunication network is an information transmission system over a communication network, containing servers connected through communication nodes and modems to client computers. The system is designed to transmit information over the network, including upon request. Modems (modulators and demodulators) are associated with transmission channels, the transceiver equipment included in the system is designed to convert network signals into signals for reception and transmission (I. Norenkov et al. Telecommunication technologies and networks, A, Izm. MSTUim. N.E.Bauman, 1998, p.31-32, 60-61, 87).

 Known systems do not allow to increase the number of serviced requests using known telecommunication networks, i.e. networks have significant customer service restrictions.

 In known systems for transmitting, encoding and / or decoding information, the image itself is. In the claimed systems, the message: information data streams, sound information and visual, visualized by representing all messages in the form of raster data.

 In other words, all known information coding and decoding systems do not use the methods of representing messages of audio, text, graphic and information recorded on information carriers and encoded with binary symbols, raster (point) data arrays of color space such as RGB, CMY, YUV, LAB, etc. .p., i.e. using digital television coding methods (RE Bykov, The Theoretical Foundations of Television, St. Petersburg, Lan, 1998, pp. 52, 56; Blanter D. et al. Scanning and Rasterization of Images, M., from ECOM, 1999, p. 50).

 The claimed systems, in contrast to the known systems, use, as a representation of the information entering the system in a very different way, the conversion of information into code sequences of data in raster color space files, which allows to obtain the following technical results.

 The technical result of the claimed nodes (systems) of encoding and / or decoding information, a data transmission system with channel multiplexing, and an information transmission system in a telecommunication network is to provide a message (text, sound, graphic, digital, analog) in the form of code sequences of coordinates of color points spaces intended for recording, storage, conversion, reading and transmission of information with the aim of using them in relevant information GOVERNMENTAL systems. This extends the arsenal of means of encoding and decoding information and allows you to visualize information in the form of graphic images using well-known means of reproduction (video monitors, etc.), to use its printed image as an array of raster point data as information carriers. The systems allow such messages to be transmitted over communication channels, including telecommunication channels with a high compression. The technical result of the claimed group of systems is the conversion of input signals from practically any message sources (audio, text, bit, graphic information) into a universal unified form of information representation, namely, into code sequences of coordinates describing color space points, for example, R, G planes, B. This makes compatible both processor systems and television systems designed to process, analyze and present and / or reproduce information, providing Chiva connection to the system a wide range of external devices.

 The technical result of the claimed systems is also the ability to visualize the sound and / or stream of digital signals in the form of a color image, such a visualization of information allows you to expand the arsenal of tools for analysis and / or synthesis of signal characteristics, and / or status, and / or other characteristics of directly information sources using visual, graphical and statistical analysis tools.

 Converting sound images (for example, musical ones) into graphic images and / or graphic images into sound ones can make it possible to synthesize visual and sound means for various purposes, including in show business.

 Using the proposed information encoding system allows you to create a cryptographic encryption system, because without information about the service information (format) when visualizing information in the decoding process, it is almost impossible to restore the original message. It is advisable to use this property when creating protective elements of money, securities, documents, secret signatures, etc.

 In addition, the use of the proposed information conversion allows you to visualize the messages presented in the claimed way by high-precision photo printing, i.e. high-resolution photo printing.

 The use of such systems in printing can significantly reduce the volume of printed documents, i.e. save paper media, in this case message visualization, i.e. their perception by a person can also be carried out using one of the options for implementing the system.

 The proposed systems allow, as mentioned above, to transmit messages using various television channels of information, as well as telecommunication networks, including the Internet, which allows to increase the number of served requests on the network. The prerequisites for the creation of the claimed systems is that the description and presentation of images, as indicated above, can be made on the basis of color models such as. RGB, CMY, YUV, etc., in which the point can be described by a numerical (code) value for each of the coordinates used, for example, in the planes "R", "G", "B". The set of points forms an image presented in a raster form in color space, resolution, i.e. the number of horizontal and vertical dots of the image field, for example, for monitors is 640x480 and 800x400. At the same time, the quantity of quantization steps in terms of the amplitude of the three color components R, G, B should be added to this value. With an eight-bit representation of the message words, you can get the message size 640x480x3x3 = 7.272.000 (bits) or 800x600x3x3 = 11.520.000 (bits) for each field Images. With a field frequency in the signal equal to 25 fields / s, this amounts to 7.372 Mbitx25 fields / s = 184.3 Mbit / s and more. This calculation is given to represent the values of possible data rates, as well as their volume 7.372x25 = 184.3 (Mbps) 11.520x25 = 188 (Mbps).

 Thus, the use of the presentation of information by raster data will ensure the compatibility of computing systems, digital television, scanning, printing, and visual presentation tools.

 The technical result in the claimed node is achieved by the fact that in the node of encoding and decoding information containing the information input unit and the information output unit associated with random access memory (RAM), a control unit connected to the control inputs of the information input unit and the information output unit and connected with RAM, a raster coding block has been introduced, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding block are connected with the corresponding moves the control unit, the bit coding section for converting information received at the input system, into the formats of external data.

 The raster coding block of the coding and decoding system contains a register, counter, encoders, a memory block, the inputs of the register are information inputs of the raster coding block, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory block, the counter inputs, the first and second encoders and the block the memory is connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory unit, the output the first encoder is connected to the address inputs of the selection of the sequence of words of the memory block, the outputs of the second encoder are connected to the address inputs of the selection of the header subzone or subzone of the words of the raster data of the memory block, the address inputs of the choice of encoding or decoding mode and the selection of the header zone or the zone of raster data are connected control unit.

 In addition, the raster coding unit additionally contains second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected to the corresponding outputs of the control unit, the corresponding output of the second register connected to the shift input of the third register.

 In addition, it may contain an element for highlighting the standard header of raster data, the input of which is connected to the corresponding output of the information input unit, the output is connected to the corresponding input of the control unit.

 The technical result is also achieved by the fact that in the information coding unit containing the information input unit and the information output unit associated with the random access memory (RAM), the control unit connected to the control inputs of the information input unit and the information output unit and associated with the RAM is entered a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are connected with the corresponding outputs of the control unit, bl a bitmap encoding for converting information received at the input system, into the formats of external devices.

 In addition, the raster coding block contains a register, counter, encoders, a memory block, the inputs of the register are information inputs of the raster coding block, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory block, the corresponding inputs of the counter, the first and second encoders and the block the memory is connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory unit, the outputs of the first the encoder is connected to the address inputs of the choice of the sequence of words of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the raster data of the memory block, the address inputs of the choice of the encoding or decoding mode and the selection of the header zone or the raster data zone are connected respectively to the corresponding outputs of the block management.

 The technical result is also achieved by the fact that in the information decoding unit containing the information input unit and the information output unit associated with random access memory (RAM), a control unit connected to the control inputs of the information input unit and the information output unit and associated with the RAM is introduced a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are connected with the corresponding outputs of the control unit, Lok bitmap encoding for converting information received at the input system, into the formats of external devices.

 In addition, the raster coding block contains a register, counter, encoders, a memory block, the inputs of the register are information inputs of the raster coding block, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory block, the corresponding inputs of the counter, the first and second encoders and the block the memory is connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory unit, the outputs of the first the encoder is connected to the address inputs of the choice of the sequence of words of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the raster data of the memory block, the address inputs of the choice of the encoding or decoding mode and the selection of the header zone or the raster data zone are connected respectively to the corresponding outputs of the block management.

 In addition, the raster coding unit additionally contains second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected to the corresponding outputs of the control unit, the corresponding output of the second register connected to the shift input of the third register.

 In addition, it may contain an element for highlighting the standard header of raster data, the input of which is connected to the corresponding output of the information input unit, the output is associated with the corresponding input of the information unit.

 The technical result is also achieved by the fact that in the information transmission system with channel compression, containing at least a codec of television signals associated with a television channel, a control unit, modulator, demodulator and communication channels, a high-resolution codec (HDTV) and nodes are introduced raster coding and / or decoding, the codec of television signals and the HDTV codec are associated with the respective nodes of the raster encoding and / or decoding, one of the nodes of the raster encoding and / or decoding is associated with information m input / output of the system, the outputs of these nodes are connected to the modulator, the inputs of the nodes of raster coding and / or decoding are connected to the output of the demodulator, these codecs, the nodes of raster coding and / or decoding, the modulator and demodulator are connected to the control unit.

 In addition, the raster coding and / or decoding unit comprises an information input unit and an information output unit associated with random access memory (RAM), a control unit for the raster encoding and / or decoding unit connected to the control inputs of the information input unit and the information output unit, and associated with RAM, a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are associated with the corresponding outputs b node control unit, a bitmap encoding unit is designed to convert information received at the input of the system into the formats of external devices.

 In addition, it contains an element for highlighting the standard header of raster data, the input of which is connected to the corresponding output of the information input unit, the output is connected to the corresponding input of the information block.

 In the system, the raster coding unit contains a register, counter, encoders, a memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, the corresponding inputs of the counter, the first and second encoders and the memory unit connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory unit, the outputs of the first the ifrarator is connected to the address inputs of the choice of the sequence of words of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the raster data of the memory block, the address inputs of the choice of the encoding and decoding mode and the selection of the header zone or the raster data zone are connected respectively to the corresponding outputs of the block management.

 The raster coding unit additionally contains second and third registers, the inputs of the second register are connected to the outputs of the memory block, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected to the corresponding outputs of the control unit, the corresponding output of the second register is connected to shift input of the third register.

 The technical result is achieved by the fact that in the information transmission system in a telecommunication network containing a server connected to the network through a switching node, a control unit associated with a modulator, a demodulator, a client computer with a monitor, raster coding and / or decoding nodes are introduced, the server is connected to the raster coding and / or decoding unit, the output of which is connected to the modulator, on the receiving side, the demodulator is connected to the client computer via the raster coding and / or decoding unit.

 In addition, in the system, the raster coding and / or decoding nodes comprise an information input unit and an information output unit associated with random access memory (RAM), a control unit connected to the control inputs of the information input unit and the information output unit and associated with RAM, a unit raster coding, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding block are connected to the corresponding outputs of the control unit, the raster coding block Bani for converting information received at the input system, into the formats of external devices.

 In addition, it may contain an element for highlighting the standard header of raster data, the input of which is connected to the corresponding output of the information input unit, the output is associated with the corresponding input of the information unit.

 The raster coding block contains a register, counter, encoders, a memory block, the inputs of the register are information inputs of the raster coding block, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory block, the corresponding inputs of the counter, the first and second encoders and the memory block are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory block, the outputs of the first encoder connected to the address inputs of the selection of the word sequence of the memory block, the outputs of the second encoder are connected to the address inputs of the selection of the header subzone or the word subzone of the raster data of the memory block, the address inputs of the selection of the encoding and decoding mode and the selection of the header zone or the raster data zone are connected respectively to the corresponding outputs of the control unit .

 In addition, the raster coding unit additionally contains second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected to the corresponding outputs of the control unit, the corresponding output of the second register connected to the shift input of the third register.

 A brief list of drawings.

 In FIG. 1 is a functional diagram of the claimed coding and decoding unit, the coding unit, and the information decoding unit. In FIG. 2 is a functional block diagram of a raster coding unit. In FIG. 3 is a functional diagram of an information transmission system with channel multiplexing. In FIG. 4 shows a system for transmitting information in a telecommunication network, including the Internet. In FIG. 5 presents a table of correspondence of the address inputs of the memory block and the contents of its memory zones. In FIG. Figure 6 shows an example of the execution of a block of raster coding in decoding mode. In FIG. 7, a possible rendering of the header and message data as a fragment of the image on a storage medium or rendering on a display screen is reproduced.

 The information encoding and decoding unit, the encoding unit and the information decoding unit (hereinafter the system) contains (Fig. 1) the following functional blocks: information input unit 1 for inputting data into the system, unit 1 reads the input signals under the control of control unit 2 , for example, a controller, one of the functions of which is the control of data transfer between the information input unit 1, random access memory 3 and the information output unit 11 associated with external devices (not shown ). Block 1 and block 11 can be connected, for example, to standard buses, such as PSI, ISA, IDE, S / P-DIF.

 The system contains random access memory 3 (RAM), while block 1 together with the control unit 2 records the incoming data in RAM 3.

 The system may also include read-only memory 24, in which data and / or programs used in the operation of the claimed systems are stored.

 The system contains a block 4 of raster coding, intended for the presentation of messages (information) arriving at it in files of graphic formats in the form of raster (point) data. A possible implementation of which is shown in FIG. 2 and FIG. 6.

 The system may also include a graphic coprocessor 6 for processing RAM data and when displaying messages connected to the monitor 2. The information output unit 11 provides coordination of the internal bus 10 with the external bus or external devices, for example, as shown above, using standard buses : PSI, ISA, IDE, S / P-DIF, where PSI, ISA are computer buses, IDE are drive buses, S / P-DIF is an interface of digital formats.

 RAM 3 is intended for temporary storage of information messages during the operation of the system and can be performed, for example, on the basis of NEC MPD481850GF-A-12 SGRAM (dynamic synchronous graphic RAM) microcircuits having a capacity of 8 Mbps (Radio Journal, N6, 1999, p. .23), consisting of two memory banks of 128 kbps of 32-bit words, there are also two 32-bit color registers and masks. These microcircuits can perform page and syllabic writing / reading, accelerated cleaning, masked data processing and content exchange between memory banks.

 ROM 24 is designed to store data used by any block of the claimed system in the process, and can be performed on the basis of masked, electrically reprogrammed, etc. ROM chips.

 The control unit 2 is designed to control the processing and input-output operations in manual or automatic mode.

 The control unit 2 can be, as indicated, a controller or processor, when used in this system, it can replace or supplement the system units, providing flexibility of the operation algorithms.

 Graphic coprocessor 6, for example, SONY CXD 8561BQ, is designed to process images, for example, received from a scanner (not shown) connected to system unit 1, in the form of a scanned image file in order to restore the raster structure of the original image from the input data message medium by alignment by means of a coprocessor of 6 lines of a raster, exact recalculation of the moved pixel data, etc.

 Raster coding unit 4 (Fig. 2 and Fig. 6) contains a register 21, the inputs of which are connected to RAM 3, connected via buses 8 to the output of the information input unit 1, the outputs of the register 21 and the outputs of the counter 12 are connected to the address inputs A2-A9 of the block 15 memory for selective control of Z block 2, the encoders 13 and 14 are connected by inputs to the corresponding outputs 17 and 18 of the control unit 2, the outputs of the encoders 13 and 14 are connected respectively to A0, A1 and A10-A12 address inputs of the memory block 15, the output 20 of the selection control encoding or decoding mode of control unit 2 By connecting the input unit A14 memory 15, the output 19 control the selection data memory area or block headers 15 are connected to the input area A13 memory unit 15, all the inputs of the storage unit 9 of the tire associated with the RAM block 11 and information output.

 In addition, in FIG. 2 shows a functional diagram of the whole coding and / or decoding systems, with each of the systems comprising an information input unit 1, an information output unit 11, RAM 3, a monitor 7, a graphic coprocessor 6, a keyboard 51 (manual data input unit), block 2 control, as mentioned above, can be a controller with standard functions. Moreover, in FIG. 2 shows the functional elements that can implement the functions of the controller in the claimed systems. The control unit contains an element 38 for switching the operating mode — encoding or decoding, an element for selecting a data zone or header zone 39, a signal supply element 40 to an encoder 14 that converts them into signals at the inputs A10-A12 of the memory unit 15 for selecting a data subzone or headers, registers 45 and 46.

Element 41 for supplying counting pulses to the counting input of counter 12, bus system switching element 42, operating, for example, by control from element 39, element 42 is connected via buses to blocks 1, 11, 6, 3, control input of register 21, counter 12 and a memory unit 15. RAM 3 may be provided with a buffer 3 _{1 for} recording and managing an interface. Element 43 is designed to supply signals to the inputs of the encoder 13, which generates a code to select the plane of the color space "R", "G", "B" and "A" at the inputs A0A1 of the memory block. Elements 38, 39, 40, 41, 42 and 43 are connected to the keyboard 51 for supplying data on them with parameters of connected external devices and commands for controlling operation modes.

In FIG. 3 is a functional diagram of a channel multiplexed information transmission system comprising a codec 22 _{1 of} television signals and a codec of HDTV (high definition television signals) 22 ₂ , respectively associated with a channel of television signals and a high resolution television channel (HDTV). The system comprises nodes 26 of raster coding and / or decoding, a modulator 23 and a demodulator 24, communication channels 29 30, a control unit 25, a control bus of the system 27 associated with blocks 22 ₁ and 22 ₂ , nodes 26, a modulator 23 and a demodulator 24, external control input 28 _{1 of the} system, designed to enter data on the parameters of the channels to be sealed and to send commands to control the operating modes of the system, information input-output 28 ₂ connected to one of the nodes 26, designed to transmit and receive additional data by the system if necessary.

In FIG. 4 presents a functional diagram of the transmission of information in a telecommunications network, including the Internet. The system comprises a client computer 49 with a monitor 50 connected to the network 32, raster coding and / or decoding nodes 26, a modulator 23. Demodulator 24, communication channels 29 and 30, control unit 25, network switching unit 31 connected to the network 32, controlling an input 28 ₁ connected to the control unit 25 and intended for inputting data about the request parameters and commands for controlling the request modes, a server 37, information input-output 28 _{2 of a} system for receiving and transmitting system data.

 In FIG. 5 is a table of correspondence of the address inputs of the memory unit 15 and the contents of its zones, the raster coding unit 4, which is part of the coding system, decoding system, coding and decoding system, information compression system with channel multiplexing and information transmission system over the telecommunication network.

Zones 35 ₁ and 35 ₂ are intended for storing header options of various formats Z ₁ -Z ₈ , which can be selected by the control unit 2. Zones 36 ₁ and 36 ₂ are intended for storing raster data in subzones D ₁ -D ₇ , in subzone D ₈ the header of raster data is stored. Zones 35 ₁ and 36 ₁ are intended for operation of the system with encoding mode, and memory zones 35 ₂ and 36 ₂ are decoded, which are selected by input A14, while either zones 35 ₁ and 36 ₁ or 35 ₂ and 36 _{2 are} activated.

Input A13 is intended to select either zone 35 ₁ headers or zone 36 ₁ raster data during encoding. When decoding, respectively, 35 ₂ and 36 ₂ .

Inputs A10-A12 are designed to select a given header of a given format from zone 35 ₁ (35 ₂ ), or, if input memory zone 36 ₁ (36 ₂ ) is activated by input A13, select data subzone D ₁ -D ₇ with the header of raster data D ₈ .

To explain the formation of data in the memory subzones 36 ₁ or 36 _2, we note how each dot of the raster data is represented in color coordinates, respectively R (red), G (green), B (blue), A (black and white) color planes.

 To do this, imagine that any point "n" of raster data can be described as n = aX, bY, cZ, mK, where X, Y, Z ... K - (1) color planes, for example, R, G, B , A.

 a, b, c, ... m is the coordinate value in the planes of the color space X, Y, Z ... K.

С учетом вышеуказанного разбиения формируют 8 подзон растровых данных Д₁-Д₇, при этом выделяют подзону Д₈ для заголовка, являющегося общим для растровых данных.For each point in the sequence of points during coding, we give the length of the values a, b, c in each of the color planes in the form of the number of bits allocated to them, for example, respectively
in the planes: R, G, B, A
for formats: GIF, 320X240 2-2-2-2
for formats: TIF, 640x480 3-3-2-0 (2)
for formats:

Taking into account the above partitioning, 8 subbands of raster data D ₁ -D _{7 are formed} , and a subzone D ₈ is allocated for the header, which is common for raster data.

 For each subzone, 8-bit words are written, formed as indicated in (2), representing sequences of combinations of the above values a, b, c, ... m; and placeholders, such as zeros, to form an 8-bit word.

In this way, possible combinations of words of raster data with respect to the color planes R, G, B, A are formed and are listed in subzones D ₁ –D ₈ .

 The claimed system implements the conversion of input information into the coordinates of the raster points and further into graphic formats of raster data. Moreover, the data (information) flow in the general case is a sequence of data elements packed in the form of a sequence of words having sizes different from the sizes of data elements of a raster file.

 Data in information systems, including those that enter the claimed encoding and / or decoding systems, have a certain structure. Formally, a data structure is defined as some well-defined area in the abstract data type that defines this structure. The data format is a certain structure of the information object being processed, recorded on a medium, displayed on a display, printed on paper, i.e. the format indicates actions, for example, recording information in a prescribed form or dividing the storage medium into sectors or zones. The format is defined using headers; headers in these systems define standard options.

 The flow of information, structured in the form of a format and not structured, is fed to the input of the system, i.e. to block 1 input information.

 The input unit 1 transfers this data to RAM 3. In accordance with the specified format, which can be specified by entering format data from the keyboard 51 of the control unit 2, or defined by the system, the system must present the data in such a way that the input information stream at the system output has been paired with an external device.

 Consider a simple example, when the format is set from the keyboard 51 (Fig. 2), consider the operation of the encoding system and the encoding and decoding system.

 The system, as intended, operates in the mode of encoding information (Fig. 1, Fig. 2 and Fig. 5).

 The input data stream, including unstructured data, i.e. without format, it enters through the data input unit 1 in RAM 3, where it is stored for the duration of processing in the system.

In this case, for simplicity of description, a command is issued to the control unit (element 38) via the keyboard 51 for implementing the encoding mode. In addition, data on the format of the external output device (bus specification) is entered into the control unit using the same keyboard, according to which the input information should be converted. The coding start signal also comes from the keyboard to all elements 38-43 of the control unit 2. Next, through the element 38, a mode selection signal is sent to input A14, a data zone or a zone of header words is selected (Fig. 2.5, input A13 element 39). Moreover, suppose that the selected memory zone 35 ₁ words of the headers Z ₁ -Z ₈ (Fig. 5).

Next, the headers Z ₁ -Z ₈ are selected by supplying selection signals from the encoder 14 to the inputs A10-A12 through the element 40 of block 2. These signals correspond to the desired header, the data about which are received from the keyboard 51 to the element 40.

The procedure for transferring the selected header Z from zone 35 of the memory unit 15 to the output unit 11 is carried out by applying counting pulses to the input of the counter 12 from the control unit (element 41), while the binary code at the output of the counter controls enumeration of addresses A2-A9 (Fig. 5) containing words that make up the selected header from zone 35 ₁ of the memory block.

Then the counter is turned off. The number of words displayed from the memory can be increased by adding to the output words a simple combination added by the signals from the outputs of the encoder 13. This procedure corresponds to the selection of additional sequences of data words. Next, the output of the most informational message received in the system from block 1 data input. To this end, a signal is inputted at input A13 to switch from the header area 35 to the data area 36, i.e. to data selection mode. Then, signals are sent to the address inputs of the selection of the data words themselves, i.e. inputs A10-A12 for selecting the corresponding subzone D ₁ -D ₇ with the heading D ₈ from zone 36 ₁ . To do this, 8-bit words of the entered data are transferred to the register 21 from the RAM 3.

Depending on the selected format, the keypad 51 sets the sequence for reading data from the selected subzone 36 ₁ D by controlling the inputs A0-A1. This is due to the fact that reading can be different for different formats. For example, it can be sequentially on the planes, first all the values of the plane R, then G, then B, or line by line, but in a known standard way, the prescribed format.

The selection of the raster words themselves color planes (2) from the selected subzone D is as follows. Data from the register 21 is supplied to the corresponding inputs A2-A9 (the counter does not work) for control from element 42 of block 2. Depending on this data, the corresponding words are selected from the specified subzone D according to the correspondence table (Fig. 5, 36 ₁ ) . Thus, at the output of the memory block, a predetermined raster data structure is formed, the format of which corresponds to the format of the external device. At the output of the output unit 11, the data is represented by graphic raster data formats.

 The decoding mode of the encoding and decoding system and the decoding system is implemented as follows.

For the case when the systems decode the data stream of the format of an external device connected to the input of the corresponding system into the format of an external device connected to the output of the system, the operation does not differ from the system in the encoding mode described above. The difference is that the data zones 35 ₂ and 36 ₂ are used in the decoding mode selected at the input A14 by the control unit 2. A signal is input at input A14 for decoding mode selection and a format is input for generating output data from keyboard 51.

 Further, the decoding process proceeds in the same sequence as in the encoding mode.

 In the case of decoding mode of graphic formats of raster data, for example, data represented by a similar coding system, it is first necessary to select the encoding parameters of the graphic format. If the graphic format does not contain a heading (it is not read by the scanner) or if it is not known in advance, that is, it cannot be entered from the keyboard, then for simplicity, select the heading of the raster data located at the beginning of the raster data in the readable block 1, for example as indicated in FIG. 7.

 The case where raster data was printed using a color printing printer connected to the output of the system output unit 11 when encoding data with the declared encoding system, i.e. recorded on the storage medium.

 On the printout, dots will be placed line by line in accordance with the encoded data on the field of the rendered message. These points can be represented in the color "R", "G", "B" or black and white A.

 Let it be necessary to decode the information printed (presented) in this way.

 In FIG. Figure 7 shows an example of visualized raster data (one line), while the data header can be highlighted, for example, by placing in the upper left corner printed in the form of a field of data points (or visualized on a monitor field of points) message sequence of 32 points, which It is performed in the same way for all graphic files of raster data of the declared coding systems. The first 8 points are made in the form of a combination of gray (halftone) points, among which dots are highlighted in red (for the R plane) that describe the number and place of significant bits of the R plane (for example, taking into account the distribution of significant bits specified in expression (2) for a given format). Zones can be allocated in another way.

 This is followed by 8 points describing the points of the green plane (G) by an appropriate combination of gray and green points.

 Next is a combination of 8 bits of gray and blue dots (plane B), the last 8 points are a combination of black and white dots (not shown).

 After that there are raster data points (not shown).

The decoding process in this case occurs as follows (Fig. 2 and Fig. 6). The scanner reads the image of the message and feeds to the information input unit 1, which transmits data to RAM 3 and to element 48 (Fig. 2) to highlight the standard header of raster data presented as described above (Fig. 7). In element 48, the incoming data from block 1 (row) and the data of the standard raster header (D ₈ ) are compared and, if they coincide, element 48 sends a signal to the format selection control element 39, after which commands for decoding and further processing are input from keyboard 51 data as described for the coding system.

 Using the keyboard 51, the command is entered into the decoding mode at input A14, the format code Z (header), in other words, the transcoding of an external device connected or potentially connected to the information output unit 11 is carried out. Block 4 is transferred to the decoding mode by supplying control signals from block 2 (initiated by the keyboard 51) along line 20 to input A14 of block 15 (Fig. 2).

Then, via line 19, a signal is input to input A13 to select the "data" or "headers" mode, then, along lines 18, a signal is sent to inputs A10-A12 to select subzone D ₁ -D ₈ or Z ₁ -Z ₈ . Then, along lines 17, the encoder 13 selects planes for the decoded word R, G, B, A or C, M, Y, K, etc. If the data during the encoding were not divided into separate bytes R, G, B, and the partition was only recorded in the header i.e. described on the demand of the format, then the corresponding subzone (D ₁ -D ₇ ) is selected on lines 18. The output in this case is output through register 46 directly. If the data arrives in the form of bytes R, G, B, A, then they are previously collected in register 45 by pushing the significant bits of the individual decoded words from register 46 for control from element 39 of block 2., and then uploaded to the bus of the information output block 11 by signals from element 42 (Fig. 6).

 The indicated process of shifting the received word into the register 45 is necessary for the bit distribution of significant bits in accordance with the distribution in the eight-bit word of all the components of a, b, c, m color areas (expression (1) and (2)).

 The decoding process itself does not differ from the encoding process described above in the encoding system.

 The data obtained during the decryption process at the output of the memory block, as indicated above, are collected in the shift registers 45 and 46 into a whole word. At the end of the decryption, the word received in the register 45 is issued to the input of the output unit 11.

An information transmission system with compression of communication channels (Fig. 3) contains a codec 22 _{1 of} MPEG signals, a codec 22 _{2 of} HDTV (high-resolution television signals), a modulator 23, a demodulator 24, bitmap encoding and / or decoding nodes 26, a control unit 25 .

The inputs and outputs of the codecs 22 ₁ and 22 ₂ are connected to the audio and video channels of television and to the audio and video channels of high-definition television (HDTV), the codec 22 ₁ and 22 ₂ are connected to the inputs and inputs of the corresponding node 26 ₁ - 26 _{2 of} raster coding and / or decoding, nodes 26 and codecs 22 ₁ and 22 ₂ on the control bus 27 are connected to the control unit 25, the control unit 25 is connected to the control inputs of the modulator 23 and demodulator 24, has an external control input 28 ₁ , the outputs and inputs of the nodes 26 are connected respectively to the modulator 23,
connected to the communication channel 29 and a demodulator 2 4 connected to the communication channel 30. The nodes 26 ₁ and 26 _{2 are} connected to the corresponding codecs 22 ₁ and 22 ₂ , the node 26 ₁ can be connected to a data source, such as the Internet, via bus 28 ₂ .

 The information transmission system with the sealing of communication channels (Fig. 3, Fig. 2 and Fig. 5) works as follows.

The nodes of the raster coding and / or decoding 26 ₁ - 26 _{3 of the} claimed system are made in the same way as in the system of encoding and decoding information (Fig. 1, Fig. 2, Fig. 5, Fig. 6) and work the same way as described for encoding mode and decoding mode.

The data of the television channel and the data of the high-resolution channel (HDTV) through the corresponding codec 22 ₁ (22 ₂ ) are input to the data input unit 1 of the node 26 ₁ and / or 26 _{2 of the} raster encoding and / or decoding, respectively (Fig. 2, Fig. 3 ) Data from the network is sent to input unit 1 of node 26 ₃ . The data is overwritten in RAM 3 in each of the nodes 26 and received in the block 4 raster coding, which implements the presentation of this data received, for example, in MPEG or HDTV, or as a digital stream (node 26 ₃ ), in a graphic format of raster data or the color TV signal standard PAL, SECAM ... as described for the encoding mode of the encoding system and the encoding and decoding system. Information about the type of coding mode and the data parameters at the output of the output unit 11 is entered from the keyboard 51, or through the control unit 25 programmatically to the elements 38-43 of the control unit 2 of the nodes 26 ₁ - 26 ₃ .

The received raster data from nodes 26 ₁ -26 ₃ in a common graphic file format or standard for color television signals is transmitted in a common stream through a modulator 23 to a communication channel 29. The control unit 25 allocates to each channel a given message length or a given number of lines (via bus 27) and reads (control bus 27) from the blocks 11 output nodes 26 through the modulator to the communication channel. The specified length or the specified number of lines for each channel can also be set by the control signal at input 28 ₁ to the control unit. The specified unit 25 can be performed as a control unit 2 in the form of a controller.

 The specified conversion allows you to encode television visual and audio messages in the form of certain lines of a raster of a television image, highlighting each television channel a specified number of lines of a raster image, i.e., the data stream unified in this way is transmitted over one channel, i.e. transmit streams from television channels and from high-resolution channels. Moreover, based on the fact that the information flow rate in a conventional television system is 135 Mbps, you can determine the number of channels that can be placed with a standard television (TV) stream.

135 Mbps: 1.5 Mbps = 90 MPEGI, z conventional resolution channels, or
135 Mbit / s: 15 Mbit / s = 9 high-resolution MPEGI, z channels and, accordingly, any combination of television streams and data streams that have passed through an encoding system containing a raster encoding unit is possible. At the same time, the amount of information that can be placed on one line of the raster image is
(720x360) x8x25 = 216 kbit / s, where
number 720 - the number of brightness elements per line
number 360 - the number of color elements
number 8 - the number of bits in a word describing brightness and color
number 25 - number of frames
From here, the required number of lines of the image raster will be
1.5 Mbps: 216 kbps - 6.944 ≈ 7 lines for conventional TV
1.5 Mbps: 216 kbps - 69.44 ≈ 70 lines for HDTV
It can be seen that the simplest way to allocate channels when they are compressed can be a method of splitting the lines of a TV image raster between different codecs, i.e., allocating a given number of lines to a channel, while additional codecs 22 are connected in the same way as codecs 22 ₁ and 22 ₂ and they can also be allocated a given number of lines. At the same time, information on the lines allocated to it is entered into the control unit 25 via the control bus 28 ₁ for each node 26. The control unit 25 controls the coding start processor in the nodes 26 and the reading process from the output unit 11 of each node 26 to the modulator. The modulator 23 and the demodulator 24 respectively perform the functions of generating the signals of the transmitter and receiver. The control unit 25, as indicated above, allocates to each channel a predetermined number of lines of the bitmap image, which are transmitted in the same sequence to the modulator 23 and then to the communication channel 29. Thus, the system allows converting all the data received on different television channels into general graphic format or color television standard and read the converted data line by line through the modulator into the communication channel.

 The information transmission system can also work in the mode of decompression of channels.

In this case (Fig. 3), the signals of several sources of information (not shown) are supplied through the demodulator 24 to the inputs of the nodes 26 (or node). The control unit 25 at the input 28 ₁ receives information about the number of connected sources and the lines allocated to it in the received data stream. The control unit 25 connects a predetermined number of data lines or a message in a predetermined number of bits to the input of the corresponding node 26, the TV channel format is entered from the keyboard, and the block 4 of the corresponding node 26 encodes the message and connects it to the corresponding codec 22 ₁ and 22 ₂ for conversion and transmission to the appropriate television channel.

 Thus, in the reverse decompression mode, the control unit 25 controls the arrival of raster information line by line (by highlighting certain lines in the received information) to the corresponding node 26. The nodes 26 convert the message into the format of television channels according to the algorithm described for the encoding system. The formatted data is transmitted through an appropriate codec 22 to an appropriate television signal receiver (not shown).

 The advantage of the system is the ability to perform all the functions of the MAC system, using the same type of coding for all signals and the ability to transmit a large number of channels, including high-resolution channels.

 Moreover, as you know, the system "MAC / packet" S.I. Alyabyev, Broadcasting and electroacoustics ", M., Radio and communications, 1999, 792 pp., Ill., P. 704, is characterized by the following features: compaction of analog and digital components with time separation, encoding of the image signal according to the MAC type, where the luminance signal and one of the two color difference signals are separately compressed and then placed within the line; packet compression for audio and data signals with digital transmission; the possibility of using identification systems, limited access, video scrambling and ekrechivaniya audio.

 At the same time, the compaction of analog and digital components with time division provides a large bandwidth at a given bandwidth of the radio channels.

 In FIG. 4 presents an implementation option of the claimed information transmission system in a telecommunication network, including the Internet.

 The system comprises a raster coding and / or decoding unit 26, a modulator 23, a demodulator 24, a control unit 25, a switching unit 21, a server 37, a client personal computer 49, and a monitor 50.

 The claimed system operates as follows.

 On the telecommunications network 32 through the switching node 31 to the server 37 receives service requests, the server 37 is connected to the network 32 through the switching node 31, or directly. Responses to requests can be received by the client over the network in a standard way. If it is necessary to transmit in an accelerated manner, the client can take advantage of the formed transmission channel that contains on the transmitting and receiving sides nodes of raster coding and / or decoding, a modulator and a demodulator. To do this, the control signal supplied to the input 28 of the control unit 25 initiates the operation of the system. The unit 25 connects the server 37 via the switching unit 31 to the control bus 27 and the responses, upon the client’s request, are sent to the raster coding and / or decoding unit 26, which is executed similarly to the encoding system and encoding and decoding system described above.

 The digital data stream from the server enters the input unit 1 of the node 26, then is overwritten in RAM 3, then by the commands from the block 25, which is connected via the control bus to the elements 38-43 of the control unit 2 of the node 26, the process of encoding data into raster graphic formats is carried out data or in the color television standard and transmit them through the output unit 11 of the node 26 to the modulator 23, through which, from the control unit 25, the data is sent to the client demodulator 24. In this case, you can use any known standard communication channels that are consistent with the flow of information.

 The demodulator receives a graphic file or image field of a CV TV response to a request, decodes it as decoded as described in the encoding and decoding system and the encoding system, visualizes it through the monitor 50 of the computer 49.

 It should be noted that the usual speed of information transmission in the telephone network does not exceed 33.6 kbit / s, which, with large amounts of information consumed, greatly stresses telephone lines and stations.

 The inventive system can serve simultaneously a maximum of 135 Mbit / s: 33.6 kbit / s ≈ 4000 people. at a speed of the telephone network or 400 people at a speed 10 times higher (336 kbit / s) or 135: 1.5 = 90 people, respectively, when transmitting at the speed of normal MPEG video. With an average volume of requested data of 10 Mbit / s, the system is capable of serving 13 people per second at a speed of 1.5 Mbit / s, or 13х60х60 = 46800 people / h, respectively.

 Taking into account the average distribution of the time of requests and the amount of data, we can assume that the actual number of serviced requests will be 10 times larger, i.e. about 500,000 people.

 Moreover, the speed of information flows from well-known Internet providers in the network of their international access is about 10-30 Mbit / s.

 The number of such providers is about 10.

 The figures show the importance of this application of the raster coding system in information transfer systems.

 In addition, the essential features of the claimed systems is that when saving raster data files on magnetic, optical media or transferring them over digital networks, the encoding depth depends only on the graphic format used and can be a maximum of 32 bits / pixel or more, since practically these operations take place without loss of information.

 When transmitting raster data, the coding depth depends only on the resolution of the receiving systems, due to interference and other features, and transmission systems, and does not depend on the type of coding in the claimed system.

 We can also say that this encoding is also carried out with the aim of harmonizing the transmission systems used, visualization, and ensuring the storage of information in the form of hard copies.

 The advantage can also be considered the possibility of using such coding in batch or frame transmission of information that are widely used at present, as well as a uniform coding method, regardless of the source data.

 It should be noted that encoding in the form of raster data is practically protected from the introduction of so-called “viruses”, since graphic files are not executable computer systems, and encoded data is used only by specific output devices: audio, video, etc.

Claims (20)

 1. The coding and decoding unit of information comprising an information input unit and an information output unit associated with random access memory (RAM), a control unit connected to control inputs of an information input unit and an information output unit and connected to RAM, characterized in that a raster coding unit has been introduced to it, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are connected to the corresponding outputs of the control unit, trova encoding for converting information received at the input node, into the formats of external devices.  2. The node according to claim 1, characterized in that the raster coding unit contains a register, counter, encoders, memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, counter inputs , the first and second encoders and the memory unit are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words of the header of the graphic format of the memory unit, the outputs the second encoder is connected to the address inputs of the choice of the sequence of words of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or subzone of the words of the raster data of the memory block, the address inputs of the choice of the encoding or decoding mode and the choice of the header zone or the raster data zone of which are connected respectively to the corresponding outputs of the control unit.  3. The node according to claim 2, characterized in that the raster coding unit further comprises second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected with the corresponding outputs of the control unit, the corresponding output of the second register is connected to the shift input of the third register.  4. The node according to claim 1, characterized in that it contains an element for highlighting a standard raster data header, the input of which is connected to the corresponding output of the information input unit, the output is connected to the corresponding input of the control unit.  5. An information encoding unit comprising an information input unit and an information output unit associated with a random access memory (RAM), a control unit connected to control inputs of an information input unit and an information output unit and connected to RAM, characterized in that a raster coding block, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding block are connected with the corresponding outputs of the control unit, the raster coding block The company is intended for converting information received at the input of a node into formats of external devices.  6. The node according to claim 5, characterized in that the raster coding unit contains a register, counter, encoders, memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, the corresponding inputs the counter, the first and second encoders and the memory block are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the header words of the graphic format of the block Names, the outputs of the first encoder are connected to the address inputs of the selection of the word sequence of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the memory block, the address inputs of the choice of the encoding or decoding mode and the selection of the header zone or the raster data zone of which are connected respectively with the corresponding outputs of the control unit.  7. An information decoding unit comprising an information input unit and an information output unit associated with random access memory (RAM), a control unit connected to control inputs of an information input unit and an information output unit and connected to RAM, characterized in that a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are connected with the corresponding outputs of the control unit, the raster coding unit It is intended for converting the information received at the input of the node into the formats of external devices.  8. The node according to claim 7, characterized in that the raster coding unit contains a register, counter, encoders, memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, the corresponding inputs the counter, the first and second encoders and the memory block are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the header words in the graphic format of the block Names, the outputs of the first encoder are connected to the address inputs of the selection of the word sequence of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the memory block, the address inputs of the choice of the encoding or decoding mode and the selection of the header zone or the raster data zone of which are connected respectively with the corresponding outputs of the control unit.  9. The node of claim 8, wherein the raster coding unit further comprises second and third registers, the inputs of the second register are connected to the outputs of the memory block, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected with the corresponding outputs of the control unit, the corresponding output of the second register is connected to the shift input of the third register.  10. The node according to claim 7, characterized in that it contains an element for highlighting a standard header of raster data, the input of which is connected to the corresponding output of the information input block.  11. An information transmission system comprising at least a codec of television signals associated with a television channel, a control unit, a modulator, a demodulator and communication channels, characterized in that a high-resolution codec and encoding and / or decoding nodes are introduced into the system, the codec of television signals and the high-resolution codec are connected to the corresponding coding and / or decoding nodes, one of the coding and / or decoding nodes is connected to the information input-output of the system, the outputs of these nodes are connected to a modulator, the inputs of the encoding and / or decoding nodes are connected to the output of the demodulator, these codecs, the encoding and / or decoding nodes, the modulator and the demodulator are connected to the control unit.  12. The system according to claim 11, characterized in that the encoding and / or decoding unit comprises an information input unit and an information output unit associated with random access memory (RAM), a control unit for the encoding and / or decoding unit connected to the control inputs of the unit information input and information output unit and associated with RAM, a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are associated with the corresponding output E node control unit, the bit coding section for converting information received at the input system, into the formats of external devices.  13. The system of claim 12, wherein the coding and / or decoding unit comprises an element for highlighting a standard raster data header, the input of which is connected to the corresponding output of the information input unit.  14. The system of claim 12, wherein the raster coding unit comprises a register, counter, encoders, a memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, the corresponding inputs the counter, the first and second encoders and the memory unit are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the words for the header of the graphic format As for the memory, the outputs of the first encoder are connected to the address inputs of the selection of the word sequence of the memory block, the outputs of the second encoder are connected to the address inputs of the selection of the header subzone or subband of the words of the raster data of the memory block, the address inputs of the choice of the encoding and decoding mode and the selection of the header zone or the zone of raster data of which connected respectively to the respective outputs of the control unit.  15. The system of claim 14, wherein the raster coding unit further comprises second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected with the corresponding outputs of the control unit, the corresponding output of the second register is connected to the shift input of the third register.  16. An information transmission system comprising a server connected to the network, a switching node, a modulator, a demodulator and a client computer with a monitor on the receiving side, characterized in that a control unit and encoding and / or decoding nodes are introduced into the system, the control unit is designed to connect server through the switching node to the coding and / or decoding node, the output of which is connected to the modulator, on the receiving side, the demodulator is connected through another coding and / or decoding node to the specified client computer.  17. The system of claim 16, wherein the coding and / or decoding nodes comprise an information input unit and an information output unit associated with random access memory (RAM), a control unit connected to control inputs of the information input unit and the information output unit and associated with RAM, a raster coding unit, the information inputs and outputs of which are connected respectively to RAM, the corresponding control inputs of the raster coding unit are connected with the corresponding outputs of the control unit, the raster unit encoding is designed to convert information received at the input of the system into the formats of external devices.  18. The system of claim 17, wherein the coding and / or decoding nodes comprise an element for highlighting a standard raster data header, the input of which is connected to the corresponding output of the information input block.  19. The system according to 17, characterized in that the raster coding unit contains a register, counter, encoders, memory unit, the inputs of the register are information inputs of the raster coding unit, the outputs are connected to the corresponding address inputs when selecting the words of the raster data of the memory unit, the corresponding inputs the counter, the first and second encoders and the memory unit are connected to the corresponding outputs of the control unit, the outputs of the counter are connected to the corresponding address inputs when selecting the header words of the graphic format bl eye of the memory, the outputs of the first encoder are connected to the address inputs of the selection of the word sequence of the memory block, the outputs of the second encoder are connected to the address inputs of the choice of the header subzone or the word subzone of the raster data of the memory block, the address inputs of the choice of the encoding and decoding mode and the selection of the header zone or the raster data zone of which connected respectively to the respective outputs of the control unit.  20. The system according to claim 19, characterized in that the raster coding unit further comprises second and third registers, the inputs of the second register are connected to the outputs of the memory unit, the outputs of the second and third registers are connected to the inputs of the information output unit, the control inputs of the second and third registers are connected with the corresponding outputs of the control unit, the corresponding output of the second register is connected to the shift input of the third register.

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