RU2152136C1 - Device for galvanic isolation and frequency correction of coaxial video transmission line - Google Patents

Abstract

FIELD: TV equipment, in particular, close-circuit TV systems (security purposes), studios, industrial usage TV equipment. SUBSTANCE: complete TV signal is output from complete TV signal source 1. Upon its transmission through coaxial transmission line, device provides galvanic isolation of signal from earth, its amplification, and regulation of its level in interface unit 4, double frequency correction in frequency correction unit 5 with respect to middle frequency (by low-frequency video signal constituent corrector 6), and high frequency (by high-frequency video signal constituent corrector 7). Then signal black level is fixed in non- controlled fixation unit 10. All video signal processing circuits are isolated with respect to power supply due to several independent power supplies 14 of power supply unit 12, which voltage converter 13 is designed using multiple-winding low-voltage transformer. EFFECT: improved image quality due to elimination of power supply lines stray pick-up. 2 cl, 1 dwg

Description

The invention relates to television technology and can be used in closed-circuit TV surveillance systems (CCTV), in studio systems, in technological television, etc. (hereinafter referred to as TV systems). High efficiency of the functioning of such systems can be realized only if the following requirements are met:
- high quality television image, which allows to realize high resolution settings of the applied video sources and, therefore, from the observation post to make competent decisions about the degree of threat to the protected object,
- the possibility in the TV system of diversity to a distance of several hundred meters of TV cameras and a monitoring station, which significantly expands the surveillance and security zone;
- high noise immunity of the TV system, the need for which is dictated by the high level of background noise arising from the implementation of TV surveillance systems, when connected to different phases of the power supply or when the equipment of the transmitting and receiving sides to different grounding points. In addition, it is necessary to take into account the presence of electromagnetic interference present in areas subject to protection or surveillance;
- the ability to correct the video signal when using a coaxial line of long length,
- high reliability of the TV system, characterizing its insensitivity to the mentioned electromagnetic interference, as well as to targeted influences on the TV monitoring system by unauthorized persons.

 Analyzing the above requirements for the TV system, we can conclude that, along with the high quality of the elements that make up the TV system, it is necessary to ensure its maximum noise immunity. However, the quality of TV images and noise immunity in some cases contradict: on long lines, with the indicated significant removal of TV cameras, an increase in noise immunity by using, for example, a coaxial cable, will lead to a decrease in the quality of the TV image due to the introduction of frequency attenuation by the coaxial cable. In addition, in most practical cases in the TV system arise, the so-called. "ground current loops" associated with the appearance of a potential difference between the grounding points of the system elements. It should be noted that in the TV monitoring system there are interference associated with pickups from power lines, and such pickups (additive distortions) are difficult to eliminate, and on the screen of the video control unit are perceived as moving luminance bands or in the form of failures in synchronization.

 Thus, high quality TV images in security and surveillance systems can be achieved by using an additional galvanic isolation device and frequency correction, which eliminates interference and corrects the amplitude-frequency characteristics of the entire circuit - from the output of the TV camera to the input of the video control unit.

 Known cable connecting line [1], containing a differential amplifier, the direct input of which is connected to the internal output wire of the incoming coaxial cable, the inverse input of the differential amplifier is connected to the potentiometer engine, the terminals of which are connected to the housing of the amplifier - splitter and the external wire of the coaxial cable. The disadvantage of this technical solution is the difficulty of tracing the coaxial cable, primarily because the cable must be insulated from ground, which is not always structurally feasible, in addition, the use of this technical solution does not solve the second problem: correction of the amplitude-frequency characteristic of the coaxial cable.

 Known receiving video amplifier-corrector (EA2010 - "Receiving video amplifier-corrector [2]), designed to correct distortions in a coaxial cable type RG-59 / U with a length of up to 900 m. This corrector allows you to adjust the total gain and additional rise separately" at low and high frequencies, however, the corrector does not suppress interference arising both from "ground current loops", and due to the penetration of additive pickups from the power lines.

 The closest in technical essence is the technical solution [3], where the purpose of the invention is the elimination of ground current loops and interference associated with interference from power lines, containing a galvanic isolation unit containing an isolation transformer designed to isolate the earth on coaxial video lines with a load of 75 Ohms . The isolation transformer contains an input bus connected via a coaxial cable to the video source, and an output bus connected to the input of the video control unit. Since the input and output busbars of the isolation transformer are isolated from each other, it eliminates the effects of power and random noise potentials between ground points on the signal lines. An isolation transformer provides earth isolation at a frequency of 60 Hz to 115 dB with a decrease of 6 dB / octave to 30 dB at least 1 MHz, with a maximum insulation voltage of 500V. The high technical characteristics of the isolation transformer provide its high operational value, however, a certain decrease in the amplitude-frequency characteristic at medium and high frequencies leads to a decrease in the quality of the TV image, in addition, the isolation transformer does not eliminate the additive noise in the video signal and, like any transformer, is the main penetration into the system of magnetic pickups, which dramatically reduce image quality.

 The basis of the invention is the principle of integrated video processing, which allows you to transmit a full television signal via coaxial cable without compromising the quality of the TV image.

 The drawing shows a structural electrical diagram of a device for galvanic isolation and frequency correction of a coaxial video line.

 The device for galvanic isolation and frequency correction of a coaxial video line contains: a video source 1, coaxial line 2, a galvanic isolation unit 3, a matching unit 4, a frequency correction unit 5, comprising a corrector 6 of the low-frequency component of the video signal and a corrector 7 of the high-frequency component of the video signal, unit 8 for suppressing additive interference comprising a matching circuit 9 and an uncontrolled fixation circuit 10, a video monitoring unit 11, a power supply unit 12, comprising a power voltage converter 13 and Atelier 14 independent voltage sources.

 The essence of the invention lies in the fact that the video signal from the output of the video signal source 1 at the stage of transmission along the coaxial line in the galvanic isolation unit 3 is galvanically "untied" from the ground, amplified and level-adjusted in the matching unit 4, undergoes double frequency correction in the frequency correction unit 5 , at medium (corrector 6 low-frequency components of the video signal) and high (corrector 7 high-frequency components of the video signal) frequencies, and is fixed by the level of black in block 10 uncontrolled fixation moreover, all the video signal processing circuits are “decoupled” by power due to the use of several independent power sources based on a multi-winding low-voltage transformer.

 The device galvanic isolation and frequency correction of the coaxial line of the video signal operates as follows. In the source 1 for generating a video signal, the optical image of the object is converted to a full television signal. The functions of block 1 can be performed by a television camera, a video switch, etc. In this case, it is important that the received video signal should be transmitted to the observation post (not shown), where the video control unit 11 is located, located from the source 1 of the video signal at a distance of several hundred meters, and the power of the source 1 is provided by the power supply unit 12 located near the unit 1 (or near block 11). From the output of the source 1 of the video signal, the video signal through the coaxial line 2 is fed to the galvanic isolation unit 3, and the unit 3, constructed on the basis of, for example, optocouplers, provides isolation of the earth and, thereby, eliminating the influence of power lines and random noise potentials between the ground points of the individual blocks devices. Most often, one has to deal with the problem of eliminating the influence of power lines due to the imbalance in the phases of the power supply arising from an uneven load on the power phases. The video signal generated by blocks 1, passed through line 2 and galvanically isolated from the ground by block 3, is sent to matching block 4, the purpose of which is to amplify and adjust the video signal by level, which allows you to compensate for losses in line 2 and in block 3. Since blocks 1 and 4 14 independent power sources are fed from separate sections of the shaper, all interference (distortions, impulse noise, etc.) arising at the grounding points of source 1, line 2, unit 3 of galvanic isolation, are localized in the zone of location of unit 1 of the form tion composite video signal (or, equivalently, 12 PSU zone). The structural diagram of the device shows that the galvanic isolation unit 3 is powered by two sources of the shaper 10 independent voltage sources. Such a diversity of supply voltages can dramatically reduce the mentioned interference from source 1, line 2 and perform further signal formation, without taking into account the negative effects that occur during the signal pre-processing stage. As indicated above, the purpose of block 4 is to compensate for the losses in line 2 and in block 3 to correct the inevitable amplitude losses resulting from the passage of the video signal through line 2, because the use of an extended coaxial line causes level loss due to the ohmic resistance of the cable (resistive component). Compensation of these losses is easy to implement by increasing the gain of block 3, but when using a coaxial cable to transmit a video signal over long distances (like line 2), amplitude-frequency distortions occur, which lead to a decrease in image clarity. To obtain a high-quality image, a frequency band of a video signal of 50 Hz - 6 MHz is necessary, then the clarity of a TV image can be 570 television lines, i.e., the maximum clarity value for a high-quality television camera. It should be borne in mind that on long lines in the specified band, the coaxial cable has not only a resistive, but also a reactive component (equivalent distributed capacitance), therefore, with an increase in the length of line 2, the transmission coefficient at high frequencies decreases, the resolution decreases and the clarity of the resulting image decreases, therefore it is necessary to provide frequency correction in two bands: 3 MHz and rise in the range of 3 - 6 MHz. Since the length (and, consequently, the loss) of line 2 depends on the design features of the system, the frequency correction is carried out in the correction unit 5 by two independent correctors: the corrector 6 of the low-frequency component of the video signal and the corrector 7 of the high-frequency component of the video signal. Block 5 provides correction of the amplitude-frequency characteristics of the entire device, which was distorted by line 2 and block 3. The elimination of multiplicative noise of the video signal is carried out in block 5 by multiplying the frequency spectrum of the signal received at the output of block 3 by a function inverse to the frequency attenuation in line 2 and in block 3, however, additive blocking cannot be eliminated with block 5, since such interference is located in the low-frequency region of the video signal (of the order of hundreds of Hz) and cannot be eliminated by filters. The device has an additive interference suppression unit 8 comprising a matching circuit 9 and an uncontrolled fixation circuit 10. After the frequency processing in block 5, the video signal is generated in circuit 9 in such a way as to provide input parameters for reliable operation of circuit 10, since the uncontrolled fixation circuit, along with certain advantages (does not require control pulses), reliably functions only under the conditions of the optimal choice of the output resistance of the previous one cascade [3]. From the output of the additive interference suppression unit 8, the video signal is supplied to the video control unit 11, which can be used as a video monitor, VCR, motion control detector, etc. A special power supply unit 12 is used in the device, comprising a converter 13 and a shaper 14 of independent power sources. Converter 13 converts the AC mains voltage into a set of AC voltages necessary to create a complex of independent power sources, each of which is disconnected from the common earth bus, and grounding is carried out according to well-known principles of low-noise equipment power supply [4, 5].

LITERATURE
1. USSR author's certificate N953746 of 04/18/78 "Coaxial connecting line."

 2. Reception video amplifier - corrector EA2010, Prospectus of Philips, 1997, p. 146, copy attached.

 3. Isolation transformer TC8235GIT, Prospectus from Philips, 1997, p. 366, copy attached (prototype).

 3. Television: Textbook for universities / V.E. Dzhakonia and others. -M .: Radio and communications, 1997, p. 328-335.

 4. Horvitz P., Hill W. The art of circuitry. Per. from English 4th ed. -M .: Mir, 1993, p. 72.

 5. V.N. Malinovsky, V.P. Prokopyshin. Methods of protection of measuring instruments for signals from general interference. Instruments and control systems, 1988, N1, p. 26-29.

Claims (2)

 1. Device for galvanic isolation and frequency correction of a coaxial video line, comprising a video signal source, the output of which is connected via a coaxial line to the input of the galvanic isolation unit, a video control unit, characterized in that serially connected matching unit, frequency correction unit, additive interference suppression unit are introduced, moreover the frequency correction unit includes a series-connected corrector of low-frequency components of the video signal and a corrector of high-frequency components of video the e-signal, the output of which is the output of the frequency correction block, the additive for suppressing additive interference contains a series-connected matching circuit and an uncontrolled fixation circuit, the output of which is the output of the block for suppressing the additive interference and is connected to the input of the video monitoring unit, and the input of the frequency correction block is connected to the output of the matching block, power supply converter, the output of which is connected to the input of the shaper of independent voltage sources, the outputs of which are connected to the pit inputs matching block, corrector of the low-frequency component of the video signal, corrector of the high-frequency component of the video signal, matching circuit, uncontrolled fixation circuit.  2. The device according to claim 1, characterized in that the block of independent voltage sources is made in the form of a multi-winding transformer, each of the windings of which is connected to a corresponding rectifier and voltage stabilizer, and the outputs of the rectifiers and voltage stabilizers do not have galvanic couplings.