RU1841024C - Video gate - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention refers to radio engineering and can be used in radar equipment for false data screening. The result is ensured by the fact that a video gate comprises an emitter repeater, a tapped delay line, an adder unit that is an output of the video gate, also comprises a non-linear amplifier and t/2 multiplying units. The above units are connected in a certain way.

EFFECT: more effective selection of high-amplitude short pulse signals with preserving the output signal duration.

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Description

The proposed video selector belongs to the field of radio engineering and is intended for use in devices that isolate and process a video signal in order to filter out false information and increase the signal-to-noise ratio at their output.

The video selector can be used in radar systems, as well as in primary information processing devices that convert the video signal into a form convenient for input into a digital computer.

Most devices that extract a useful signal from noise and noise are based on a method of increasing the signal-to-noise ratio by storing the energy of periodically following video signals on the elements of static and dynamic memory for a number of periods of their succession. An example of such devices is incoherent video signal storage devices made on the basis of CRTs, 3 CRTs (storage CRTs), magnetic drums, a signal adder on storage capacitors, drives on delay lines with positive feedback, as well as on the basis of storage devices with temporary video signal selection and quantizing it by level (digital drives of binary pulse signals). In addition, the category of detectors includes signal detectors made on the delay lines with inter-period comparison (the method of coincidence) and processing according to the criterion ″ K ″ from ″ m ″, see S.V. Samsonenko ″ Digital methods for optimal processing of radar signals ″, 1968, p. 96-108. M.I. Finkelstein, ″ Basics of Radar ″, 1973, p. 226, 235; 251-257. ″ Radio Engineering Systems ″, ed. Yu.M. Kazarinova, 1968, p. 146-151.

Prototype, i.e. the device closest in composition to the proposed technical solution is a video noise discriminator with a delay of the detected pulse, the description of which is given in the materials of US patent No. 3.124.707 of March 10, 1964

The video noise discriminator contains a delay line with taps, the input of which is connected, for example, the output of a video amplifier, and a terminating resistor to its end. The taps on the delay line are made at equal time intervals and are placed along the line evenly, i.e. taps divide the delay line into a series of time delay sections.

The inputs of the same type of transistor amplifiers are connected to the taps of the delay line. The transistor collectors are connected to a common load - a resistor, through which a supply voltage is supplied to them. The connection point of the transistor collectors to the resistor is the output of the device according to the total signal. Thus, the inputs of the adder of video signals are connected to the taps of the delay line.

An increase in the signal-to-noise ratio at the output of the video noise discriminator with a delay of the detected pulse is achieved by the fact that, as they move along the delay line of the video signal, video pulses and noise, with a sequential delay in the sections of the line, pass through the taps to the delay lines to the inputs of the adder. At the adder load, the signals are summed. The addition of the components of the video pulse phased within the pulse duration, but shifted relative to each other, leads to the fact that the signal amplitude increases at the adder load, and subsequently, when the signal exits the delay line, it decreases. The output pulse takes the form of an isosceles triangle, and the pulse duration at the base doubles (if the duration of the input signal and the duration of its delay in the line are equal).

Addition of uncorrelated noises at the adder load does not cause large changes in their amplitude. Noises within the delay of the signal in the line have a random phase and amplitude of the frequency components. Noises are condensed, but practically do not increase in level. The difference in the increase in the amplitude of the processed video pulse and the noise at the output of the video noise discriminator leads to an increase in the signal-to-noise ratio at the output of the device relative to its input. As follows from the description of the patent, increasing the signal-to-noise ratio at the output of the video noise discriminator reaches 7 dB.

The disadvantages of the prototype include the weak screening of short interfering signals of large amplitude and a significant extension of the duration of the emitted signals, which leads to smoothing of the front boundaries of the pulse due to slow rise and fall, this leads to erosion of the outlines of the radar image on the indicators, and the presence of short impulse noise makes it difficult to isolate useful information by automatic processing and signal extraction equipment when working on a digital computer.

The aim of this invention is to increase the efficiency of screening by the video selector of short pulsed large-amplitude interference while limiting the duration of the signals at its output and, as a result, increasing the reliability of the processing of incoming information in subsequent devices and increasing the quality of the display of the radar image on the indicators screen, increasing its clarity.

,This goal is achieved by the fact that in the video selector containing an emitter follower, a delay line with ″ n ″ taps, the input of which is connected to the output of the emitter follower and the adder, the output of which is the output of the device, is matched to the input and output, a nonlinear amplifier and ″ m are introduced into the video selector ″ Multipliers. The output of the nonlinear amplifier is connected to the input of the emitter follower, and the input to the output of the video amplifier of the radar system. The outputs of the multipliers are connected, respectively, to the inputs of the adder, and their inputs, in pairs, to the taps on the delay line, the delay time interval between which is chosen equal $$(0,5-\mathrm{one},5)\cdot \frac{\Delta t_s\cdot m}{n-\mathrm{one}}$$

,

where Δt _s - the delay time of the signal in the delay line,

m is the number of multipliers, and n is the number of taps on the line, counting the beginning and end of the delay line.

The presence of a non-linear amplifier at the input of the video selector allows, depending on the tasks to be solved and the signal-to-noise ratio specified at the input of the device, to provide the necessary amplitude correction of the input signals, to form the end-to-end characteristic of the device, and thereby increase the efficiency of eliminating interference and noise.

, обеспечивает отсев коротких импульсных сигналов большой амплитуды (импульсных помех, отдельных шумовых выбросов и т.д.), имеющихся на входе устройства и укорочение длительности входного сигнала.The inclusion in the video selector ″ m ″ analog multipliers, with a pair of connecting their inputs to the taps on the delay line, through a delay interval equal to $$(0,5-\mathrm{one},5)\cdot \frac{\Delta t_s\cdot m}{n-\mathrm{one}}$$

, provides the screening of short pulsed signals of large amplitude (pulsed interference, individual noise emissions, etc.) available at the input of the device and shortening the duration of the input signal.

Connecting the outputs of the ″ m ″ multipliers to the outputs of the adder, taking into account the time shift of their output signals at the inputs of the adder, provides an increase in the signal-to-noise ratio at the output of the device (by analogy with the prototype), and the formation of pulses at its output with a duration equal to or close to input signals. Technical solutions that coincide in conjunction with the hallmarks of the proposed device are unknown to the authors.

In FIG. 1 shows a block diagram of a video selector, and FIG. 2 shows time diagrams explaining his work.

The non-linear amplifier 1, the emitter follower 2, the delay line 3, ″ m ″ of the same type of analog multipliers 4, 5, 6, 7 and the adder 8 are included in the video selector.

The video selector is implemented mainly on the basis of analog integrated circuits (AIS) using precision operational amplifiers. Nonlinear amplifier 1 is made on the basis of an operational amplifier, for example 544UD2A, covered by feedback with linear and nonlinear parallel branches (for example, using diodes). The output of the video amplifier of the radar system is connected to its input.

The emitter follower 2 is assembled on a semiconductor triode, the output of which is connected, via a matching resistor, to the delay line 3, and the input to the output of the nonlinear amplifier 1.

Delay line 3 is a broadband delay line with focused parameters, to the end of which a terminating resistor is connected. A number of signal taps a, b, c, d, d, e, f, z are made on the delay line. The delay time of the signal in the line Δt _{s is} chosen equal to the expected duration of the useful signal or slightly less. The taps of the delay line 3 are connected in pairs to the inputs of the multipliers 4, 5, 6, 7, etc. (inputs of 1, 2 multipliers).

.As multipliers, AISs are used, for example, of type 525PS2, the outputs of which 1, 2, 3, 4 are connected to the inputs 1, 2, 3, 4 of the adder 8. The inputs of each multiplier are connected to the taps of the delay line 3 in pairs. The time interval of the signal delay between the taps is chosen equal to $$(0,5-\mathrm{one},5)\cdot \frac{\Delta t_s\cdot m}{n-\mathrm{one}}$$

.

Each subsequent pair of multiplier inputs, relative to the neighboring, previous pair, is connected to the taps with a sequential time shift from the beginning of the line to its end so that all pairs evenly overlap the entire delay line 3. For the specified number of taps, the pair connections of the multiplier inputs can be as follows: for example , a-d, b-e, v-zh, G-z (basic version) or a-e, b-d, v-z, g-z, etc.

For a more effective elimination of noise by the adder 8, the number of multipliers is chosen equal to 4 or more (5-8).

The adder 8 is based on an operational amplifier, for example, 544UD2A, to the output of which an emitter follower is connected. The output of the emitter follower of the adder and the input of the operational amplifier are covered by feedback. To the feedback resistor, at the point of its connection to the input of the operational amplifier, ″ m ″ of the same type of parallel resistors is connected. The free ends of the resistors are the inputs 1, 2, 3, 4 of the adders 8, to which the outputs of the multipliers are connected. The output of the emitter follower of the adder 8 is its output, i.e. device output. The input of the signal limiter of the primary information processing device and, in parallel, the indicator input can be connected to the output of the adder.

The operation of the video selector is as follows.

The video signal, a mixture of video pulses and noise, through a non-linear amplifier 1 and a cathode repeater 2 is fed to the input (H) of the delay line 3. Moving along the delay line, the video pulses, through taps on the line, are sequentially fed to the inputs of the multipliers 4, 5, 6, 7. From The principle of operation of the analog multiplier is known that the magnitude of its output signal is determined by the product of the amplitudes of the signals at its inputs. If at one of its inputs there is zero potential, and at the second one, the signal at the output will be zero. When two single signals of equal amplitude arrive at both inputs, the signal at the output of the multiplier will be equal to unity (condition for coincidence).

When a long video pulse passes through the delay line 3, the components of which within its duration have the same amplitude and phase, the conditions are provided for the pulse to simultaneously overlap the delay time interval between two taps on the line to which the inputs of, for example, the first multiplier are connected. With the further advancement of the video pulse along the delay line 3, these conditions are satisfied for subsequent multipliers. In this case, signals of equal amplitude and same phase will be allocated at the outputs of the multipliers, and the duration of the output pulse will be shortened by the amount of signal delay in the corresponding interval between the taps. At the inputs of adder 8, ″ m ″ signals will appear, shifted relative to each other by the mutual shift of the paired inputs of the multipliers along the delay lines 3. At the output of adder 8, a signal will be formed in the form of an isosceles triangle (as in the prototype), the duration of which, based on will be close to or equal to the duration of the input signal (depends on the order of connecting the inputs of the multipliers to the taps on the delay line). See the diagrams in FIG. 2.

If there are 3 short pulse signals of large amplitude at the input of the delay line (interference pulses, noise bursts, etc.), the condition for coincidence of the signal components at the two inputs simultaneously for any of the ″ m ″ multipliers is not fulfilled. In this regard, there will be no signal at the outputs of the multipliers, there will be no signal at the output of the adder 8, i.e. at the output and the entire device. The device as a whole works like a high pass filter. For noise, due to the significant delay interval between the taps, to which the inputs of the multipliers are connected, the probability of coincidence of their components with equal amplitude and phase is also reduced. Noises are becoming more rare. A further increase in the signal-to-noise ratio is provided by the adder, as in the prototype, because at its load, the summation of uncorrelated noise is performed with a significant time shift of the signals at its inputs.

By summing the time-shifted allocated shortened pulses coming from the outputs of the multipliers, the output of the adder provides the formation of an output signal with a duration equal to or close to the duration of the input pulse. See FIG. 2d, e.

Timelines illustrating the operation of the video selector are shown in FIG. 2. On the graphs, the case of connecting the inputs of the multipliers to the taps on the delay line is considered according to the most rational scheme a-d, b-e, v-z, g-z. In FIG. 2a, b, c, d show graphs of successive advancement of the input pulse relative to the corresponding pair of inputs of the multiplier, and in FIG. 2d four output signals generated by each of 4 multipliers. The short pulse shown against the background of a long signal is encrypted.

The total pulse received at the output of the adder 8 is shown in FIG. 2e. The graphs show that short pulses are not summed. In FIG. 2d, the output pulses of the multipliers 4, 5, 6, 7, for clarity, are indicated by the indices B ₄ , ₅ , ₆ , ₇ , and in the graphic image the delay lines, the taps paired to the inputs of the corresponding multiplier are indicated by the number of the multiplier. The scale for all timelines is identical.

The use of a video selector in the video channels of radar stations, telemetry, and other radio engineering systems that receive and process pulsed signals can significantly reduce the effect of noise interference and individual short pulsed signals on information processing. At the same time, noise reduction and an increase in the signal-to-noise ratio at the output of the device are provided.

The duration of the emitted useful signal is practically equal to the duration of the input pulses. This allows for greater reliability of the selection of useful information, to preserve the resolution of the radar, and when choosing a certain level of signal restriction at the input of subsequent devices, to reduce the effect of noise and individual noise emissions of large amplitude. to a minimum. The screening effect of short pulse signals can be most effective when the signal-to-noise ratio specified at the system input (for example, when receiving relayed signals) is greater than unity.

Reducing the effect of noise and impulse noise on information processing allows to increase the noise immunity of the system, increase the range of the radar and improve the conditions for the allocation and resolution of targets, increase the clarity of the radar image on the indicator screen.

When using a video selector in combination with a signal limiter and primary information processing devices with its subsequent output to a digital computer, significantly greater reliability of the solution of the tasks is provided.

An experimental verification of the proposed technical solution confirmed the operability of the device and its effectiveness.

Depending on the specific use of video selector products in the equipment, the economic effect of using the invention can be significant - tens of thousands. Hardware products can be greatly simplified.

Claims (1)

A video selector comprising a series-connected emitter follower and a multi-tap delay line, as well as an adder whose output is the output of the device, characterized in that, in order to increase the selection efficiency of short high-amplitude pulsed signals while maintaining the duration of the output signals, a nonlinear amplifier and m / 2 are introduced multipliers, and a non-linear amplifier is connected between the input of the device and the input of the emitter follower, the inputs of the i-th multiplier are connected to the i-th and $$(\frac{m}{2}+i)-m$$

taps of the delay line, i = 1, 2 ..., m / 2,
m is the number of taps of the delay line, the outputs of the multipliers are connected to the corresponding inputs of the adder.

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