RU2011310C1 - Method of transmitting digital information in tv channel frequency range - Google Patents

Abstract

FIELD: communication engineering. SUBSTANCE: even number of additional carriers are transmitted in the top part of frequency band of TV channel being free from spectra of carriers of video- and audio TV signals to form sequent set of pairs, separated for frequency; spectra of the pairs are not mixed. Each pair of adjacent additional carriers is modulated by its own digital signal by means of frequency manipulation without phase breaking. The frequency of modulation is above than tone frequency. Modulation index is chosen to be less than unit and/or frequency band of manipulated carriers is restricted preliminary in the parts which don't belong to these carriers. EFFECT: improved precision of transmission. 2 dwg

Description

 The invention relates to communication technology and can be used in broadcast and cable television (TV) systems for transmitting information in digitally encoded form.

 A known method of transmitting digital information in the frequency band of a TV channel, according to which the digital signal is transmitted via an additional transmission channel, organized by temporarily compressing the transmission channel of the video-TV signal.

 This method, which has been widely developed in Teletext systems, allows the transmission of information exclusively under the condition of the operation of a TV-video signal transmitter. Systems embodying this method are characterized by a low information transfer rate, considerable complexity and cost.

 A known method of transmitting digital information in the frequency band of the TV channel, according to which, as in the invention, in the upper part of the TV channel band, free from the spectra of the carrier video and audio-TV signals, transmit oscillations of an additional carrier modulated by a digital signal.

 This method extends the service of subscribers to the TV channel in terms of transmitting additional audio signals to obtain stereo effects or multilingual accompaniment of the TV video program. However, in it, to modulate the additional carrier, the method of relative coded quadrature phase shift keying (OKFMn) is applied, which determines the rather complicated design of the receiving device and significant hardware improvements in the audio-TV transmitter, necessary for organizing the transmission of a TV program with enhanced service from one studio.

 There is also a method of transmitting digital information in the frequency band of a TV channel, according to which, as in the invention, at least two additional modulated carriers are transmitted in the upper part of the TV channel band, free from the spectra of the video and audio-TV signals digital signals.

 This method is a prototype in comparison with the known method considered, it is characterized by a large amount of transmitted digital audio information, from which the subscriber can choose the following options at his discretion: to receive any one sound signal on his receiver to receive speech accompaniment of the TV program in the language he needs or receive two beeps at the same time to receive stereo music sound. However, within the framework of this method, a complex method of phase modulation of carrier digital information signals has been applied, which limits its widespread use in broadcast TV due to the high expected cost of a subscriber receiver.

 The task to which the invention is directed was to provide the possibility of organizing new low-cost information transmission systems, including both local computer networks and a broadcast network, with a minimum of hardware improvements in existing TV transmitters in combination with a low cost of equipment for subscribers. Thus, the claimed technical result from the use of the invention is a constructive simplification and reduction in the cost of digital information transmission systems in the frequency band of the TV channel.

 The achievement of this technical result is due to the fact that in the method of transmitting digital information in the frequency band of the TV channel, which consists in the fact that in the upper part of the TV channel band, free from the spectra of the carrier video and audio-TV signals, transmit at least two additional carriers modulated by digital signals, according to the invention, the number of additional carriers is chosen even, the pairs formed by adjacent additional carriers are spaced in frequency to ensure their spectra are not mixed, and the modulation is exist by frequency manipulation without phase discontinuity in one pair of neighboring additional carriers with one digital signal, the manipulation frequency being chosen in the region of supratonal frequencies, the modulation index being chosen less than unity and / or the bandwidth of the frequencies of the manipulated carriers in the parts lying outside the pairs of these carriers is preliminarily limited.

 We show that between the set of essential features of the invention and the achieved technical result there is a stable causal relationship.

 The basis of the proposed method on the method of frequency manipulation (FSK) without phase discontinuity for modulating additional carriers is a priori determined by the fact that the hardware implementation of the method of FSK without phase discontinuity is simpler than the method of phase shift keying (PSK): since there is no need to create synchronous and in-phase oscillations at the reception oscillation in the transmission eliminates the need for a bulky device, which, due to its complexity, has low reliability. At the same time, the frequency-modulating principle of the operation of traditional audio-TV transmitters was also taken into account, which predetermines the minimum of hardware improvements in the latter for organizing the transmission of additional digital information in a standard TV channel in case of using the FMN method. Here, one should probably also pay attention to the fact that the signs “manipulation of two additional carriers” and “continuity of the phase of these carriers” are inseparable, since, otherwise, it is impossible to reliably distinguish between “0” or “1” on receiving part of the system.

 Reliable reception of one digital signal (one stream of digital information) that manipulates one pair of neighboring additional carriers, and a second digital signal that manipulates another pair of additional carriers, is possible only with such a frequency spacing, when there is no mixing of the spectra of these pairs, either between themselves and with spectra of the carrier video and audio TV signals of this channel.

 The overtonality of the manipulation frequency in any pair of additional carriers is mandatory due to the frequency-modulating principle of the operation of traditional audio-TV receivers: otherwise, sound interference to the subscriber of the traditional TV information is created, making it difficult for him to properly configure his TV program.

 From the consideration of the frequency distribution in the TV channel band, regulated by GOST 7845-75, it can be seen that there are only 125 kHz in the upper part of the channel band for placing additional carriers (taking into account the indicated non-mixing of the spectra). As the calculation showed, taking into account the fact that for the transmission and restoration of a rectangular pulse of a digital signal without significant loss of pulse parameters, at least three harmonic components should be transmitted and received, with a modulation index m ≥ 1, even one pair of frequency-manipulated additional carriers cannot be placed in the 125 kHz section without mixing with the spectrum of the carrier of the audio-TV signal of the channel or without mixing with the spectrum of the video-TV signal of the adjacent channel. Therefore, the invention is regulated by m <1. However, on the other hand, if under certain conditions of transmission (for example, a high transmission speed of an information signal is required or a high level of interference is inherent in a communication channel), it will be necessary to select a modulation index close to unity (for example, m = 0 , 8), then again, you can "not fit" into the area a = 125 kHz. Then it is also necessary to preliminarily limit the frequency spectrum band of the pair of manipulated carriers in parts lying outside the pair. This can be done without sacrificing the reliability of the transmitted information, since the two sidebands of each pair of manipulated carriers carry the same information (which means that one carrier of each carrier can be filtered out), and the transmission times of these carriers do not coincide (which means you can filter out "external" bands, allowing the frequency overlap of the "internal" side bands in a pair of manipulated carriers). Under certain transmission conditions, it may be appropriate to combine such an “external” restriction of the spectrum bands of a pair of manipulated carriers with a choice of modulation index according to the condition m ≥ 1. Thus, the claimed modulation index m <1 "and" preliminarily limit... Outside the pair of these carriers "is regulated by means of an" and / or "combination of features... Outside the pair of these carriers, the actions that must be performed to" fit "the pairs of additional carriers into a small free area are regulated TV channel and in combination with other features of the method to ensure reliable transmission of digital information in a real communication channel in compliance with the required protective relations. It is clear that only thanks to the combined action of these two features can one, two, three independent channels for transmitting digital signals be organized.

 Thus, it can be considered proven that the entire claimed combination of essential features of the method is necessary and sufficient to solve the problem with the achievement of the claimed technical effect.

In FIG. 1 shows the frequency allocation in a broadcast TV radio channel; FIG. 2 - an example of the placement of the spectra of two pairs of additional frequency-manipulated carriers in the upper free part of the frequency band of the TV channel, f ₁ , f ₂ , f ₃ , f ₄ - additional carriers, f ₅ - the carrier of the video-TV signal, f ₆ - the carrier of the audio-TV signal, a is the width of the free part of the frequency band of a traditional TV channel, l ₁ , l ₂ is the frequency spacing in the pairs of manipulated carriers, F ₁ , F ₂ are the frequency bands of the manipulated pairs.

 The method is as follows.

At the first stage, a preliminary calculation of the conditions for the placement of additional carriers f ₁ , f ₂ , f ₃ , f ₄ in the upper part a = 125 kHz of the TV channel band free from the spectra of the carrier f ₅ and f ₆ video and audio TV signals is performed (Fig. 1). The total number of additional carriers must be even for the possibility of the formation of i pairs of neighboring carriers (f ₁ -f ₂ , f ₃ -f ₄ ), in each of which frequency manipulation will be performed without phase disruption with its ith digital signal ζ _i = ζ ( t) transmitted, for example, from a central computer to a series of subscriber computers. The starting point of the calculation is the required data rate, or rather, the frequency f _{i of the} transmitted rectangular digital signal, which should be supertonal (f _i > 16 kHz). Taking into account the fact that for transmission and restoration of a rectangular pulse without significant losses, it is necessary to transmit and receive at least three harmonic components of the modulating function ζ _i = ζ (t) with a maximum power level, the width Δ f _{i of the} spectrum of the transmitted message can be estimated by the relation
Δf _i = 3˙K˙f _i , where K is the correction factor depending on the transmission conditions in the real radio channel (0.2 ≅ K <1).

Thus, the width of the spectrum of each of the carrier f ₁ , f ₂ , f ₃ , f ₄ is equal to 2Δ f _i . The frequency spacing l _i in each pair of manipulated carriers (Fig. 2) is determined taking into account the modulation index m _i according to the relation l _i = m _i Δ Δ f _i . Initially, it is possible to choose m _i = 1, since the transmission times f ₁ and f ₂ (f ₃ and f ₄ ) never coincide. Taking into account the obtained values of Δ f _i and l _{i, we} next evaluate the possibility of placing pairs of carriers f ₁ -f ₂ and f ₃ -f ₄ in the band a = 125 kHz of the TV channel, being guided by the inadmissibility of mixing their spectra. If it is not possible to ensure that the spectra of i pairs of additional carriers are not mixed with each other or with the spectrum of the carrier f _{6 of the} audio-TV signal of a given channel without going beyond its upper boundary, then try to narrow the bands F _{i of} each manipulated pair (or one of them ) To narrow the strip F _i, you can go in three ways: either by reducing the value of m _i (thereby decreasing l _i ), or by limiting (cutting) the strip F _i in parts lying outside the pairs of these carriers, or simultaneously vary as the value of m _i , and the degree of “external” trimming of the strip F _i . As noted above, filtering by one sideband for each frequency-manipulated carrier in the i pair (of course, provided that the transmission of the second bands is complete) does not theoretically affect the reliability of the transmission of the digital signal ζ _i = ζ (t).

 Based on the results of such an approximate basic calculation, it is recommended to conduct mock studies (to clarify the value of K) on a prototype system, for example, computer communications in the frequency band of a TV channel, the results of which will significantly reduce the debugging time of a system working with a real TV channel.

Guided by the generally accepted rules for ensuring high protective ratios in the TV channel, the power levels of the transmitted additional carriers f ₁ -f ₄ can be set 10 dB below the level of the audio carrier of the TV signal.

 The implementation of this method when organizing local computer networks is possible using a transmission and reception system made according to the well-known block diagram: on the transmitting side, a sequential chain "a computer interface unit - frequency manipulator - FM radio transmitter" is organized, and on the receiving side - a serial chain "superheterodyne FM radio receiver - computer interface device". Circuit and technical solutions of the blocks are simple and involve the use of cheap commercially available element base. The computer interface device on the transmitting side includes a controller with a buffer, and on the receiving side of the system, it is a serial chain "comparator - buffer - controller". A frequency manipulator, providing phase continuity in a pair of manipulated frequencies, can be performed, for example, in the form of a sinusoidal voltage oscillator, in the oscillating system of which a controllable reactive element is included.

 The organization of a broadcast computer network or network as part of the existing system of cable TV signals of the transmitter of the indicated block diagram, i.e., the implementation of the proposed method does not entail any changes in the standard equipment of the TV systems. The execution of the receiving part can be performed universally for all three cases considered.

 It is clear that the organization of parallel transmission of not one, but, for example, two digital signals (Fig. 2) can be coupled with the parallel connection of two transmitters of the same circuit design to the same antenna, and at the same time, two parallel receiving circuits can be provided in the subscriber’s receiver.

Claims (1)

 METHOD FOR TRANSMITTING DIGITAL INFORMATION IN THE FREQUENCY BAND OF THE TELEVISION CHANNEL, which consists in transmitting at least two additional carriers modulated by digital signals in the upper part of the band of the television channel, free of charge, characterized in that the number of additional carriers carriers are chosen even, pairs formed by adjacent additional carriers are spread in frequency with non-mixing of their spectra, and modulation is carried out by frequency manipulation without phase discontinuity in one pair adjacent one additional carrier digital signal, and manipulation frequency is selected in the supersonic frequency, a modulation index is chosen less than unity and / or pre-limited frequency spectrum band carrier manipulated in parts lying outside these pairs of carriers.

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