RU2103836C1 - Method of transmission of additional discrete information in composition of full television signal and device for its realization - Google Patents

Abstract

FIELD: information transmission systems. SUBSTANCE: in compliance with method of transmission of additional discrete information in composition of full television signal line synchropulses are modulated on sending side in duration by signal of additional discrete information. Line synchropulse of standard duration corresponds in this case to zero signal of additional discrete information and synchropulse having duration half as short as that of standard one corresponds to one. Demodulation and reconstruction of initial additional information take place at receiving side. EFFECT: increased informational capacity of full television signal. 4 cl, 6 dwg

Description

 The invention relates to techniques for television and can be used in discrete-type information transmission systems.

 There are a number of methods for sealing television (TV) communication channels with additional information [1,2,3]. However, their common and significant drawback is the incomplete use of the information capacity of the TV channel. This is due to the fact that introducing additional information into the TV channel, which consists of a full television signal (PTS) and a sound pairing signal, the opportunity to increase the information capacity of a full television signal is not used.

 Closest to the technical nature of the invention is a method of forming a TCP described in [4, pp. 50-51]. However, this method also does not use the ability to increase the information capacity of the TCP.

 The purpose of the invention is to increase the information capacity of a full television signal by transmitting additional discrete information to its composition.

 This goal is achieved by the fact that in the method of forming a TCP, in which the generated full television signal is a combination of image signals, damping and synchronizing signals, moreover, the damping and synchronizing signals are transmitted through the communication channel simultaneously with the image signals, and horizontal and frame synchronizing signals are transmitted Moreover, in the redistribution of the same time intervals as the corresponding damping ones, the synchronizing signals are located above the damping ones, in the region of black, "horizontal synchronization signals are modulated by the duration of signals of additionally transmitted discrete information, while the zero signal of additional discrete information corresponds to the standard duration of the horizontal synchronization signal, and a single signal of additionally transmitted discrete information corresponds to a horizontal synchronization signal, the duration of which is two times less than the standard, thereby, additional information signals with the possibility of their subsequent guide selection on the reception side.

 The invention is illustrated in FIG. 16.

 Consider the very possibility of introducing additional information in this way. For this, we consider the structure of clock signals in a TCP described in [5, p. 3, fig. 2 a, b] and shown in FIG. 1 application materials. So, the structure of the TCP clock signals is as follows: five frame clock signals with a duration of q = 27.3 μs each [5, Table 1, pp. 6–7] with “insets” between them with a duration of μ = 4.7 ± 0.2 μs each follow ; then follows a sequence of five equalizing signals of duration p = 2.35 ± 0.1 μs each; after which 304 (three hundred and four) lowercase sync signals with a duration of d = 4.7 ± 0.2 μs each follow; what follows is another sequence of equalizing signals, completely similar to the first. After that, the picture is repeated.

 These clock signals provide TCP synchronization on the receiving side in frames and rows. Frame and line synchronization signals vary significantly in duration to facilitate their recognition at the receiving side, however, synchronization is affected not by their duration, but only by the squareness of the shape of the clock front [6, p.232].

 Thus, if in the mixture of PTS clock signals, the duration of the horizontal clock signal is modulated so that a signal of duration d = 4.7 ± 0.2 μs corresponds to zero, and a signal of duration d / 2 = 3.35 ± 0.1 μs to the unit of additional discrete information transmitted then it becomes possible to transmit additional information as part of the TCP. Moreover, the quality of synchronization and, consequently, image restoration at the receiving side will not deteriorate if the clock fronts do not worsen their squareness.

 Consider now the technical solution. \\ 2 A system implementing the proposed method is shown in FIG. 2 and comprises a device for transmitting additional discrete information signals as part of a TCP 1, a relay 2 and a device for receiving additional discrete information signals transmitted as a part of a TCP 3.

 There are many known devices for transmitting additional discrete and analog information to a TV channel, for example [7,8]. However, all of them do not allow to implement the proposed method.

 Of the known devices, the closest to the proposed one in technical essence is a device for transmitting a full television signal, containing a series-connected transmitting station, a linear amplifier, an intermediate amplifier and a transmitting camera, the three control inputs of which are the first, second and third outputs of the clock generator, respectively, the fourth output of which is connected with the control input of the intermediate amplifier, and the fifth output of the clock generator is connected to the control input of the linear amplifier, and about written in [6, p. 226, fig. 172]. But this device also does not allow to implement the proposed method.

 The purpose of the proposed device for transmitting signals of additional discrete information in the IPR is to increase the information capacity of the full television signal. This goal is achieved in that in a device containing a series-connected transmitting station, a linear amplifier, an intermediate amplifier and a transmitting chamber, the three control inputs of which are the first, second and third outputs of the clock generator, respectively, the fourth output of which is connected to the control input of the intermediate amplifier, and the fifth the output of the clock is connected to the control input of the linear amplifier, the fifth output of the clock is sequentially through the synchronizer and an additional source discrete information is connected to the control input of the synchronizer. This achieves the implementation of the proposed method on the transmitting side.

 A functional diagram of the proposed transmission device is shown in FIG. 3 and contains a transmitting chamber 4, an intermediate amplifier 5, a linear amplifier 6, a transmitting station 7, a clock 8, a synchronizer 9 and a signal source for additional discrete information 10.

 The transmitting camera 4 serves to convert the optical image into an electrical signal carrying information about this image. The principle of construction and operation of the camera is described in detail in [6, p. 84 - 119]. The intermediate amplifier 5 and the linear amplifier 6 are designed to amplify the electrical signal with the output of the camera 4 to values at which the signal can be transmitted at a distance from the TV camera to the transmitter. For this, the transmitting chamber 4, the intermediate amplifier 5 and the linear amplifier 6 are connected in series. In the linear amplifier 6, in addition, the formation of the TCP occurs, namely, the mixing of image signals and synchronization. These amplifiers are also widely covered in [6, p. 144 - 168].

 The transmitting station 7 serves to convert the TCP received at its input to a form convenient for transmission, its amplification and transmission to the repeater.

 The synchronizer 8 is intended for the formation of synchronizing pulses; which are transmitted as part of the TCP to enable image recovery on the receiving side, that is, using the sync generator, the transmitting camera 4 is synchronized, the process of forming the TCP in the linear amplifier 6 and image recovery on the receiving side. The principle of construction and operation of the sync generator is also covered in the well-known literature, for example, [6, p. 243 - 257]. However, the synchronizer 8 has a slight circuit difference from those described in the literature, since it is necessary to provide modulation of horizontal sync pulses in duration. Technically, this is achieved by introducing a key into a conventional synchronizer, which is controlled by signals from a source of additional discrete information 10. For this, the output of source 10 is connected to the control input of the clock generator, and it, in turn, is connected to the control input of the key. At zero potential, at this control input, a regular horizontal sync pulse with a duration of d = 4.7 ± 0.2 μs enters the mixture of clock pulses. If the potential input is received at the control input of the key, then a pulse is mixed into the mixture of clock pulses, two times shorter in duration. In the technical design of the synchro-generator, the control sync-pulse generated by the synchro-generator can serve as such a pulse, since it satisfies the duration conditions: its duration is p = d / 2 = 2.35 ± 0.1 μs.

 The source of additional discrete information 10 may be different: ADF (data transmission equipment), ADC (analog-to-digital converter), etc.

 Based on the nature of the proposed method, the transfer of additional information is possible only while following lowercase, and not other synchronization pulses. This condition is fulfilled using synchronizer 9, for which a mixture of clock pulses is fed to its input, and the output is connected to the control input of source 10. A schematic diagram of synchronizer 9 is shown in FIG. 4 and contains a frame sync pulse allocation block 11, summing the counts at eight 12 and 13, a counter at five hundred and twelve, decoders for extracting the number five in binary code 15 and 16 and the number three hundred four in binary code 17, AND element 18, 19, OR element 20 and the element is PROHIBITED 21. The block allocation of the frame clock 11 is not disclosed in detail, since this is not necessary. This unit is inherently a pulse selector in duration and is technically implemented in any existing TV. Its presence in the synchronizer 9 provides a rigid frame-by-frame synchronization of the sides of the system.

 Although the synchronizer 9 is described by a separate paragraph 3 in the claims, it cannot claim to be an exceptional novelty, since having a circuit novelty and personality, in general it is a selective counter. Therefore, the authors inform in advance that they will completely agree with the opinion of the examination about the need to describe the synchronizer in a separate paragraph of the claims. The operation of the synchronizer 9 is described in detail below.

 A device for transmitting signals of additional discrete information as part of a TCP works as follows.

 The optical image to be transmitted is projected onto the mosaic of the transmitting television tube using a lens. In the tube, it turns into an electric one and a potential relief appears on the photomosaic. An electric beam under the action of deflecting coils, fed by a sawtooth voltage, alternately runs around all the elements of the photomosaic and reads the potential relief. At the same time, an image signal (video signal) arises at the output of the transmitting tube, which is amplified and fed to the output of the transmitting camera 4. At the same time, the clock 8 generates certain sequences that ensure the operation of the device elements. At the same time, a mixture of damping and driving pulses enters the transmitting camera. The mixture of damping pulses also enters the intermediate amplifier 5, where the video signal is amplified. Line amplifier 6 also amplifies the signal, however, it mixes the video signal and the mixture of clock pulses coming from the fifth output of the clock 8. In addition, the mixture of clock pulses (figure 1) is fed to the input of the synchronizer 9 (figure 4).

 As soon as the first frame sync pulse arrives at the output of the synchronizer 9 from the mixture of clock pulses, a single pulse appears at the output of the frame sync pulse extraction unit 11, which is counted by the counter 12. The next frame pulse is also allocated and counted by the counter 12. As can be seen from figure 1, there will be five frame sync pulses . All of them are allocated by block 11 and summed up in counter 12. With the arrival of the fifth frame pulse, the combination at the output of counter 12 will be read by the decoder 15, which is configured to extract the number five in binary code. A single potential at the output of the decoder 15 will allow the passage of subsequent synchronization pulses through AND 18. These will be control pulses, which, in the amount of five pulses, will pass through the open PROHIBIT 21, will be sent to the counter 13 are summed. As soon as all five control pulses are received, the potential of the unit appears at the output of the decoder 16, which, through the ban 21, will prohibit the passage of other clock pulses to the counter 13 and, in addition, through And 19 will allow the passage of pulses following the mixture equalizing the counter input to the counter 14. These are horizontal sync pulses.

 Following the equalizers, 304 (three hundred and four) line impulses follow. All of them are counted by the counter 14. As soon as the three hundred and fourth pulse is received, a unit appears at the output of the decoder 17, which will reset all the counters, after which the synchronizer 9 will return to its original state before receiving the next frame clock. However, at the time when the horizontal sync pulses are being counted, the output OR will have a single potential, since one of the bits in the counter will be in the single state during the count. This potential is fed to the output of the synchronizer 9 and then to the control input of the source of additional discrete information 10. Thus, the presence of a logical unit at this input indicates the possibility of transmitting additional discrete information, which is bit by bit fed to the control input of the clock 8 and then to the key included sync generator. This key kneads a standard horizontal sync pulse at a value of a bit of additional information into a mixture of clock pulses. If the bit of additional information has a single value, then an impulse with a duration of two times less than the standard one (equalizing impulse) enters the mixture. The resulting mixture from the fifth output of the sync generator 8 receives the input of the synchronizer 9 and the control input of the linear amplifier, where the video signal is amplified and mixed with clock pulses. The resulting mixture is called a full television signal. From the output of the linear amplifier 6, it enters the input of the transmitting station 7, is converted to a form convenient for transmission, amplified and transmitted to the air.

 Depending on the range in which the television signal is transmitted, repeater 2 can be either a terrestrial or a satellite repeater (artificial Earth satellite). For the case of cable television or when transmitting a TV signal over short distances, the repeater may not be available. However, for the general case, it is shown and exists for the purpose of receiving a signal from a transmitting device, amplifying it, and transmitting it further to a receiving device 3.

 There are many devices for receiving additional information transmitted as part of a TV broadcast signal. However, none of them allows you to select from the TCP information entered by the proposed method.

 Of the known devices, the closest in technical essence is the device described in [6, p.323, Fig. 239], containing a high-frequency channel, the output of which is simultaneously connected to the input of the audio interface channel and the first input of the image channel, the output of which is the input of the selector synchronization pulses, the output of which is connected to the inputs of the first and second separation filters, the output of each of which is connected respectively to the first and second inputs of the scanner, the three outputs of which are connected respectively but to the second, third and fourth inputs of the image channel. However, this device is also not able to implement the proposed method.

 The purpose of the proposed device for receiving a signal of additional discrete information transmitted as part of a full television signal is to increase the information capacity of a full television signal.

 This goal is achieved in that in a device containing a high-frequency channel, the output of which is simultaneously connected to the input of the sound channel and the first input of the image channel, the output of which is the input of the synchronization pulse selector, the output of which is connected to the inputs of the first and second separation filters, the output of each which are connected respectively to the first and second inputs of the scanner, the three outputs of which are connected respectively to the second, third and fourth inputs of the channel The receiver of signals of additional discrete information, a synchronizer and a signal selector of additional discrete information, the input of which is simultaneously the output of the synchronization pulse selector and the input of the synchronizer, the output of which is connected to the control input of the signal selector of additional discrete information, two outputs of which are connected respectively to the first and second inputs, are introduced receiver of signals of additional discrete information.

 A diagram of the proposed device is shown in FIG. 5 and contains a high-frequency channel 22, a sound channel 23, an image channel 24, a synchronization pulse selector 25, separation filters 26 and 27, a scan unit 28, a signal selector for additional discrete information 29, a synchronizer 30, and a receiver signals of additional discrete information 31. Names of such blocks of the device as high-frequency channel 22, sound channel 23, image channel 24, synchronization pulse selector 25, isolation filters 2 6 and 27 and the scanner, talk about their appointment as part of the TV receiver. All of them are described in the literature, for example, [6, p. 32 - 347] and, in addition, technically implemented in any TV. Therefore, the authors found it possible not to provide a more detailed description and principle of operation. As for the description of the static relationships of these elements, they are given in the claims and are clearly visible in figure 5.

, которое обеспечивается элементом задержки 34. Величина этого времени есть среднее значение от длительности тех импульсов, которые несут значение передаваемого бита дополнительной информации.The separator of signals of additional discrete information is a pulse in duration. Its circuit solution (one of the options) is shown in FIG. 6 and contains the And 32 element, RS - trigger 33, the delay element 34, PROHIBITION 35 and 36. A mixture of synchronization pulses is fed to one And 32 input, and an enable signal from the synchronizer 3 to the other. It should immediately be said that it is completely similar to the synchronizer 9 transmission devices. Thus, a rigid frame-by-frame synchronization is also provided at the receiving side, and the presence of a unit potential from the output of the synchronizer 30 permits the separation of additional discrete information signals from the mixture of clock pulses. To do this, from the output And 32, the mixture enters the S - input of the trigger 33, which is reset to the initial zero state by the signal from its output after the delay time

which is provided by the delay element 34. The value of this time is the average value of the duration of those pulses that carry the value of the transmitted bit of additional information.

 The pulse generated at the output of the trigger is fed to the inverse input of the PROHIBIT 35 and the direct input of the PROHIBIT 36, the other inputs of which receive a sync-mixture. If the duration of the synchronization pulse from the mixture is longer than the pulse at the trigger output, then a single pulse will appear at the output of PROHIBIT 35, which means that the value of the bit of additional information is zero. If the impulse from the mixture is shorter than the impulse at the output of the trigger, then a single impulse will appear at the output of PROHIBIT 36, which indicates a single value of the bit of additional information. Thus, the appearance of a single pulse at one or another output of the separator 29 indicates the significance of the information bits. In accordance with these values, the signal receiver 31 conducts further information processing. The signal receiver of the additional discrete information 31 is selected depending on what is their source on the transmitting side. This can be an ADF, DAC (digital-to-analog converter), etc.

 Let us evaluate the technical and economic efficiency of the invention.

 According to GOST [5], a TV image with the number of lines equal to 625 at 25 fields per second is accepted in the USSR. However, to transmit signals of additional discrete information in each field, only 304 horizontal synchronization pulses can be used (Fig. 1). Thus, the information capacity of the additional channel formed as part of the TCP for transmitting discrete information is 304 • 25 = 7600/8 bytes, which is enough to transfer data to six ADF terminals operating at speeds of 1200 bps plus the transmission of address messages before sending this information .

 It is also appropriate to add that the costs of implementing this transmission network will be minimal, since its main equipment (transmitting stations and cameras, repeaters and TV receivers) already exist, that is, this network can be created on the basis of any existing TV broadcast network. In this case, the deterioration of image reproduction quality is not observed.

Sourse of information:
1. Auto USSR N 924918, class H 04 H 7/08, 1982.

 2. Auto USSR N 1042207, class H 04 H 7/08, 1983.

 3. Auto USSR N 1109952, class H 04 H 7/08, 1984.

 4. Blinder E.M., Burman S.L. Television - M.: Radio and Communications, 1984.

 5. GOST 7845-79. Broadcast Television System. Main parameters. Measurement Methods.

 6. Kostykov Yu.V., Krzhitomovsky V.D. Fundamentals of television - M.: Ministry of Defense of the USSR, 1965.

 7. Auto USSR N 657665, class H 04 H 5/38, 1979.

 8. Auth. St. USSR N 856036, class H 04 H 7/08, 1981.

Claims (4)

 1. The method of transmitting additional discrete information as part of a full television signal, in which the transmitted information is synchronized and included in the composition of a full television signal, characterized in that the introduction of additional discrete information signals in a full television signal is carried out by modulating the duration of the horizontal sync signals, while zero a signal of additional discrete information corresponds to a horizontal line signal of standard duration, and to a single signal an additional Relative discrete information corresponds to the horizontal sync signal, the duration of which is two times less than the standard.  2. A device for transmitting additional discrete information signals as part of a full television signal, comprising a series-connected transmitting camera, an intermediate amplifier, a linear amplifier and a transmitting station, as well as a clock generator, the first, second and third outputs of which are connected respectively to the three control inputs of the transmitting camera, and the fourth and fifth outputs of the clock are connected respectively to the control input of the intermediate and linear amplifier, characterized in that the last atelno connected synchronizer and more discrete information source, whose output is the control input of the clock, the synchronizer input connected to a fifth output clock.  3. A device for receiving additional discrete information signals transmitted as part of a complete television signal, comprising an image channel, the output of which is an input of a synchronization pulse selector, characterized in that a synchronizer, an additional discrete information signal selector and an additional discrete information signal receiver are output the synchronization pulse selector is simultaneously connected to the synchronizer input and the control input of the signal extractor additional discrete information.  4. The device according to PP.2 and 3, characterized in that the synchronizer contains the first, second and third totalizing counters, the first, second and third decoders, the frame sync pulse allocation unit, the first and second AND elements, the OR element and the BAN element, direct input which simultaneously is the synchronizer input, the first input of the second AND element and the input of the frame sync pulse allocation unit, the output of which is connected to the counting input of the first totalizing counter, the outputs of which are connected to the inputs of the first decoder, the output of which о is connected to the first input of the first AND element, the second input of which is connected to the output of the FORBID element, and the output of the first AND element is the counting input of the second totalizing counter, the outputs of which are connected to the inputs of the second decoder, the output of which is simultaneously connected to the inverse input of the FORBID element and the second input the second AND element, the output of which is connected to the counting input of the third totalizing counter, the outputs of which are simultaneously connected to the inputs of the OR element and the third decoder, the output of which is simultaneously associated with the reset input totalisers, moreover, an output of OR is the output of the synchronizer.

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