ITNA970019A1 - SYSTEM FOR THE SIMULTANEOUS TRANSMISSION OF SEVERAL ANALOGUE TV PROGRAMS ON A SINGLE CHANNEL AND THE RECONSTRUCTION IN RECEPTION OF THE AUTOMATIC SIGNALS - Google Patents

Description

DESCRIPTION of the industrial invention having as title: System for the simultaneous transmission of several analogue TV programs on a single channel and the reconstruction in reception of the audio and video signals of the single sources.

SUMMARY

A system for the simultaneous transmission of multiple television programs on a single TV channel is illustrated, consisting of an encoder, which mixes the audio and video signals of multiple sources, and the relative decoder, which is able to reconstruct the audio and video signals of start for each source, and the characteristics of the signal capable of carrying the relative information between the encoder and the decoder are defined.

DESCRIPTION

Starting from the observation that the saturation of the available television channels has long been reached, the aim was to create a system that would allow multiple television programs to be sent on the same carrier, in order to expand the capabilities of the many analogue systems currently existing. . The system described offers a solution to the problem of compacting the information present in analogue television signals and has been designed to allow the simultaneous transmission of multiple analogue television signals with interlaced frames, black and white or color, compliant with PAL, NTSC or SECAM standards, with or without the related audio channels, on a single physical transmission channel, cable, optical fiber or radio waves, maintaining the same standard of the source signals, and reconstruct, upon arrival, the individual starting analog video and audio signals ; the information that allows the reconstruction of the video signals and that relating to the audio channels are inserted in digital form in the composite video signal, in correspondence with the frame return lines.

The system consists of two distinct devices: an Encoder, which processes the incoming audio and video signals and their formatting, generating an intermediate composite video signal at the output, and a Decoder, which extracts the audio and video signals. video of the desired program from the same composite signal.

THE ENCODER

The encoder, schematically presented in figure 1 of the attached Table 1, selects the individual fields of each image and their digital marking: the encoder decides, according to algorithms that take into account the number of programs to be mixed and the dynamism of each scene. , the sources of belonging of each pair of fields to be transmitted in a frame; a code, containing the univocal indication of the sources to which the odd and even fields in the transmission queue belong, which may be different, is written before sending the first field of each frame, in one of the trace return lines.

With reference to the block diagram, the Video Multiplexer, switching on vertical synchronisms, selects from the video of the different program sources, Video 1, .., Video N, single fields, in the chosen sequence, which will then be the one reported in the code prepared by Identifier Generator, and generates a composite video signal, Video Mix, in which frames containing odd and even fields follow one another, as in the normal transmission of a single TV signal, with the peculiarity that not all fields belong to the same source; the identification code of each pair of fields is added to the signal in one of the frame return lines, by means of the Teletext Line Modulator. If you want to assign an equal number of fields to each of the video sources, the sequence will be chosen so as to alternatively take the odd and even fields of each source at regular time intervals. Figure 3 of the attached Table 2 represents some examples of fixed sequences and random sequences: sequence A is a fixed sequence of fields, odd and even, belonging to two sources; sequence B is again a fixed sequence of fields belonging to three video signals; sequence C, on the other hand, represents a random succession of fields coming from two sources, video 1 and video 2, of which the first presents more dynamic scenes than the second and therefore requires the transmission of a denser number of fields.

The audio relating to one of the programs, Audio 1, continues to be transmitted in analog mode on the audio subcarrier, in the manner envisaged by the chosen standard, through the Audio Subcarrier Modulator; those relating to the other programs, Audio 2, .., Audio N, are digitized, through the relative encoders, Audio Converter 2, .., Conv. Audio N, packaged in strings preceded by an identifier assigned by the Identifier Generator and inserted, via the Teletext Modulator, on frame return lines.

The blocks for processing the audio information, the converters and the audio sub-carrier modulator are considered omitted when the system is designed for the transmission of images only.

The signal obtained from the encoder, Video Out, is therefore still a composite video signal, having a format identical to that of the incoming sources, PAL, NTSC or SECAM and containing the video and audio information relating to all the incoming programs. This signal is sent to a modulator, if you want to transmit it over the air, that is, it can be transmitted via cable or optical fiber.

THE DECODER

The decoder is able to separate and reconstruct the information relating to each single source present in the intermediate composite video signal, analyzing the frame return lines and extracting the identifier of the pair of incoming fields, in order to select the fields relating to the chosen source. , and data packets relating to digital audio channels. A block diagram is represented in figure 2 of the attached Table 1: the blocks relating to the management of the audio are understood to be suppressed when only video signals are to be received. The line containing the identification of the pair of incoming fields is extracted from the Video Input signal, entering from the AV interface, by means of the Video ID Line Processor which, upon recognition of a field belonging to the selected program, enables the Semi-frames Selection circuit. In the case of repetitive sequences of fields belonging to a predetermined number of sources, the selection of the fields belonging to a particular source can be entrusted to a counter and, in this case, the receipt of the identification will serve as the counter synchronization signal. The incoming composite video signal, CVBS Input, passes into the Video Input Processor circuit, which separates the synchronisms and, for color transmissions, separates the luminance signals from the chrominance signals; the Video signal, containing only the luminance information, or luminance and chrominance in the case of color images, enters the A / D converter; the converter will be single for black and white images, dual or triple for color images, depending on the treatment technique of the luminance and chrominance information, Y-UV or RGB; the conversion is enabled by the Semi-Frame Selection circuit to digitize the Video signal only for the desired fields; the output data are deposited in the appropriate locations of the Frame Buffer, which is a fast digital memory, with a capacity suitable for containing the number of samples established for the frame; the width of each word, number of bits fixed for each sample, will generally be equal to 8 bits for B / W images; it will go up to 12, 16 or 24 bit for color images, depending on the input processor used (Y-UV or RGB) and the desired image quality. The frame memory is read continuously, odd field area and even field area, at the frame rate of the television standard used and the data reconverted into an analog signal by the DAC Conversion block; The DAC output (single for B / W signals, dual or triple for color signals) is sent to the Video Output Processor, which in the case of color images reconstructs an analog composite video signal, and inserts the synchronism signals . The presence of the frame memory is essential for the correct functioning of the whole system, as it allows the continuous output presentation of the image from its own content, even when this is updated only a few times per second. The source identification code is Hamming protected and the Video ID Line Processor discards those codes for which a reception error has occurred, so that, in the presence of disturbances that do not allow a certain attribution of the incoming fields, the content of the frame memory remains unchanged and the previously stored image is presented. The reconstructed video signal, CVBS Out, is sent to the TV or monitor via the Γ AV Interface.

A more detailed diagram of the field selection circuit is presented in Figure 4 in Table 2: in it, the information relating to the type of sequence selected and the identification of the incoming fields are separated from the string outgoing from the video ID line processor. , by means of the two decoders of sequence code and field identification; the programmable sequencer that enables the gate on the arrival of the vertical synchronism (V-Sync) is programmed by the first decoder and is synchronized by the second when the sequence code indicates that the sequence is fixed; otherwise, the sequencer directly compares the identifiers provided by the relative decoder with the one requested; the field selection gate is enabled by the sequencer to generate the clock required by the A / D converter; the sequencer also generates the selection signals for the frame memory (odd bank or even bank).

An Audio Line Extractor, similar to the Teletext lines extractor, recognizes the lines that contain audio data relating to the selected program and extracts the data, downloading them into a memory, Buffer FIFO, Γ data extraction takes place in real time, all within the row range. The FIFO is downloaded at a constant frequency during the whole frame period, towards the Audio D / A Converter, which reconstructs the original audio channel. The audio channel associated with the program, the one input to the decoder for one of the programs, In Analog Audio Channel, or the one derived from the Audio D / A Converter for the other programs, will then be sent out from the Audio Selector, Out Audio Channel, towards l AV interface.

THE INTERMEDIATE COMPOSITE VIDEO SIGNAL

The intermediate signal generated by the encoder contains, in an analog composite video format, meeting the chosen standard, be it white-black 525 or 625 interlaced lines or PAL, NTSC or SECAM colors, all the information relating to several audio / video programs.

Each field present in the intermediate signal can belong to a different source: a code, containing the identifiers of the pair of fields, odd and even, in the transmission queue of each frame is inserted in a trace return line; the line can be pre-assigned, by choosing for example line 16, for compatibility with the VPS system, or it can be dynamically chosen, among the free ones, by assigning to the string comprising the code one of the possible magazines of the Teletext standard, and specifying in one of the bit if the code relates to the current or the next frame.

In other track return lines, in a variable number according to the number of channels requested, the data relating to the audio channels are contained in digital form. Formatting is provided for the audio channels, compatible with the Teletext standard, with a protected Hamming header, containing in the first 8 bits a packet identifier, magazine plus line, and a mode code in the following 4 bits. The mode code indicates the type of audio, mono or stereo; a particular mode provided is the non-audio data transmission mode, useful for transmitting programming and configuration information towards the decoder.

An essential characteristic of the intermediate signal is the intrinsic parametric flexibility: there is no fixed number of sources to mix, there is no pre-established sequence in the order of the fields, no particular line is set for the transmission of the identification codes of the fields, as well as the lines on which to transmit the additional audio channels are not fixed. All these parameters can be programmed from time to time, depending on the number of programs to be transmitted at the same time, the number of frame return lines of the television standard adopted, which generally provides from 14 to 44 lines that can be used on 525 or 625 total lines, and the availability of frame return lines left free by other types of services, Teletext, VITS, VPS and others, which normally use these.

Briefly, the characteristics of the signal format can be summarized as follows:

Lines usable for data transmission: any line available.

Lines that can be used for data, in the presence of video frames: from line 7 to line 22 and from line 320 to 325 for systems 625 lines and 50 fields per second, black and white or color; from line 10 to 14 of both fields for systems of 525 lines and 60 fields per second, black and white or color. In the 625/50 system it is possible to occupy, when necessary, another 32 lines, 16 for the odd fields and 16 for the even ones, arranged at the beginning and at the end of each panel.

Field sequence: sequence of odd and even fields each belonging to any of the transmitted video sources.

Audio of the first source: analog, AM or FM (depending on the standard) on audio carrier.

Data line identification: compliant with CCIR957 (Teletext) specifications.

Digital data bit rate: 444xfh (6.9375 Mbit / s) for 625/50 systems; 364xfh (5.7272 Mbit / s) for 525/60 systems.

Field identification static coding line: line 16 (VPS system data).

Line for dynamic field identification coding: any line that can be used for data. Field identification coding: variable code length, depending on the coding system, from 1 to 6 bytes.

Lines for digital audio channels: any line usable for data.

Audio data string header: 24 bit (3 bytes), Hamming protected; 12 useful bits: 3 bits for the magazine (one magazine is assigned to audio data), 5 bits for the row (one row is assigned to each audio channel), 4 bits for the mode, including the data mode.

Length of audio data or programming data packets: 39 bytes (312 bits) for 625/50 systems; 31 bytes (248 bits) for 525/50 systems

SYSTEM PERFORMANCE AND USES

The performance of the illustrated system depends on the number of programs to be transmitted simultaneously and on the dynamism of the scenes: two programs can be transmitted simultaneously without any observable degradation. In the case of a large number of programs, the encoder must be equipped with a selection algorithm capable of analyzing the movements of the scenes of each of them and dynamically adjusting the number of fields of each source transmitted in the unit of time.

In addition to the transmission over the air or other physical means, cable or optical fiber, of several television programs on a single channel, the system can certainly be used in other sectors, including:

a) Transmission of multiple video signals, or video plus data, analog or digital, via cable or over the air, in surveillance and monitoring systems.

b) Recording on a single magnetic support of several video or audio-video sources.

An intrinsic peculiarity of the system is represented by the encryption effect deriving from the video information from the alternation of sources and the additional audio information from their digitization. The system is therefore also suitable for the transmission of audiovisual information directed to a restricted range of users, who have the decoder.

Claims (11)

CLAIMS 1) The format of the intermediate signal is claimed, as described, having in an analog composite video, 625 or 525 lines per frame, in black and white or in color, with PAL encoding, or NTSC, or SECAM, the relative video information to several television programs, or audio / video sources, or video sources with or without the addition of digital data, in addition to an audio channel, mono or stereo, on the relative sub-carrier, and, encoded in the track return lines, from time to time chosen and assigned for this purpose, the remaining audio channels, mono or stereo, digitized and the signals necessary for the extraction and complete reconstruction of audio, or data, and video of each source. 2) The complete system is claimed, consisting of the encoder capable of generating the intermediate signal, starting from analog audio-video signals, in black and white, or in color, standard PAL, or NTSC, or SECAM. and by the decoder capable of extracting and reconstructing audio and video of the selected sources. 3) The encoder claims the solution of inserting, through a multipiexer, synchronous with the frame return signals and programmable as a sequence, in a video signal consisting of a continuous flow of odd and even fields, according to any of the current standards for the black-white or for color, PAL, NTSC or SECAM, a generic sequence, ordered or random, of fields coming from two or more different video sources, after marking each pair of fields, by means of a binary code, written in one of the return lines of the switchboard and showing the information suitable for identifying the sequence and sources of origin of the pair of fields in the transmission queue. 4) The solution is claimed in the encoder to digitize the additional audio channels required, identify them with a header that indicates the nature of digital audio signals, such as stock number, the associated video source, as a line number, and the mode, mono or stereo, and format them with a head compatible with the Teletext standards, inserting them in the composite video signal as per claim 1, inside track return lines free from other services. 5) The solution is claimed in the decoder of reconstructing the image of any of the video sources from the analysis of the mixed composite video signal referred to in point 1, identifying, in a static way, when the number of the line containing the information is preset, or dynamic, by reading the header of the lines assigned for this purpose, the trace return line in which the recognition code of the two incoming fields has been deposited, analyzing the content of the field assigned to contain the code and, as a function of this, allowing the transit and processing of only the fields belonging to the selected source, which are digitized and sent to the frame memory. 6) In the case of signals containing fixed and repetitive sequences of fields belonging to a predetermined number of sources, the decoder claims the possibility of selecting the fields of the chosen source through a counting circuit which is increased by the frame synchronism and re-synchronized by the identification code. 7) The decoder claims to use a digital frame memory, with the relative A / D and D / A conversion circuits, to obtain a reproduced image that is always stable, at the frame rate of the chosen standard, whatever the frequency refreshment determined by the encoder for the fields relating to the scenes of the single selected source. 8) The solution is claimed in the coder to discard, considering them as not belonging to the desired source, those fields for which the identifier extractor, protected with Hamming coding, reports an error, keeping and presenting again, and until the arrival of a new field identified with certainty, the content previously stored in the digital frame buffer. 9) In the decoder, the solution is claimed to identify dynamically those containing audio data, having a header formatted according to the Teletext standards, and by the number of the packet, recognize its nature and source and store those relating to the source selected sequentially, during the row period, in a FIFO memory which is read at constant speed during the frame period, in order to be able to convert its content back into the starting analog audio information . 10) The solution is claimed in the decoder of being able to automatically recognize, from the header of the digitized audio data packets, whether the transmission is mono or stereo and, depending on the mode, configure the decoding circuits of the audio signal. 11) In the decoder the solution is claimed to be able to recognize and receive, from the header of the digitized audio data packets, in the presence of a particular pre-assigned code, a string which, instead of audio data, contains digital remote command and programming data addressed to the decoder itself.