RU156824U1 - TRANSVERSAL ANALOGUE FILTER FOR RECEIVING OF CHF OF MICROWAVE SIGNAL - Google Patents

Abstract

A transverse analog filter for receiving a microwave frequency signal of the microwave range, containing a set of channels for signal transmission, each of which contains an elementary phase circuit and is connected by its output to the input of the power adder, characterized in that the signal is supplied to each channel through a power divider, the number of channels is determined the pulse width of the chirp signal, and the elementary phase circuits are made in the form of segments of transmission lines, for example, microstrip lines, the length of which is selected so that I the signal on each channel corresponds to the time of appearance of local maxima chirp signal having a slope of the dispersion characteristics of the inverse dispersion slope received chirp signal.

Description

The utility model relates to radio engineering and can be used in radar and data transmission devices. A transverse analog filter (TAF) is designed to receive linear frequency modulation (LFM) signals with specified parameters such as center frequency, frequency deviation, pulse duration.

The problem of receiving signals in radar and data transmission is a small signal-to-noise ratio, the useful signal is lost against the background of noise and cannot be extracted by simple means, such as, for example, a band-pass filter.

Two main methods are known for isolating weak signals from a signal-to-noise mixture: the accumulation (integration) method and the method based on the use of complex signals. The accumulation method is used for periodic or quasiperiodic signals of long duration. In microwave technology, this method requires the transfer of the received signal down the spectrum, for its digitization and further accumulation.

One of the most common complex signals is a linear frequency modulated signal. To detect the LFM signal, it is most convenient to use a digital matched filter, which also requires the transfer of the received signal from the microwave region down the spectrum to the region of intermediate frequencies suitable for digitization.

A digital transverse filter is known from the prior art [patent RU 2119242, IPC H03H 15/00], which implements convolution using N delay elements, N multipliers and N-input adders-shapers of the output signal.

The disadvantages of this technical solution is the dependence of the spectrum width of the processed signal on the sampling frequency and the inability to directly digitize the microwave signal. Thus, in the microwave range, the use of digital filters is possible only with frequency transfer down the spectrum, which seriously complicates the signal processing system, and also requires taking into account weighting factors and, as a result, multiple multiplication operations.

The prototype is a signal convolution device [RU patent No. 2290751, IPC H03H 17/06], containing elementary phase circuits, proportional links and adders. The device implements a parallel-serial scheme for constructing a transverse filter, in which the input signal is divided into the required number of channels, based on the required filter order, the signal of each channel is multiplied by its own weight coefficient, and the output adder is implemented on a chain of elementary adders, and elementary phase adders are included between the adders contours. The prototype additionally uses the output of a copy of the time-delayed input signal. Presented in the prototype scheme for calculating the convolution of the signal implies that all elementary phase circuits provide the same delay, selected by the sampling frequency of a similar digital filter, and samples of the impulse response are specified using weighting coefficients, in the general case complex. For an LFM signal, this will mean taking a sample of the impulse response at points where the impulse response can take arbitrary values from minimum to maximum, including values close to zero. Presented in the prototype circuit of the device involves obtaining a copy of the original signal on each branch with compensation for signal power loss and without considering the coordination of resistances.

The transition to the microwave range requires mandatory coordination of the circuit resistance by power, and signal branching is possible only with the help of certain devices, such as tees, dividers and power couplers of the microwave range, and is associated with the division of the input signal power. Elementary phase loops must have the required broadband and phase stability. In this case, elementary phase circuits must have either small intrinsic losses, or losses must be taken into account in proportional links. Thus, the transfer of the structure of the prototype directly to the microwave region requires the development of a filter structure for detecting the LFM signal again, taking into account the design features of microwave devices and transmission lines.

The technical result that you want to achieve is the creation of a system for detecting the LFM signal of the microwave range, providing an incomplete convolution of the received LFM signal with itself.

The task that is posed during the development of this utility model is to ensure the detection of the LFM signal of the microwave range due to the operation of calculating the incomplete convolution function between the received and reference LFM signal, which is accompanied by noise suppression and the formation of a signal with a pronounced maximum at the output of the TAF.

This technical result is achieved due to the fact that the transverse analog filter for receiving the LFM signal of the microwave range contains a set of channels for transmitting the signal, each of which contains an elementary phase circuit and is connected by its output to the input of the power adder, moreover, the signal is supplied to each channel through a power divider, the number of channels is determined by the pulse width of the chirp signal, and elementary phase circuits are made in the form of segments of transmission lines, for example, microstrip lines and the length of which is chosen so that the signal propagation time through each channel corresponds to the time of occurrence of local maxima of the LFM signal having a slope of the dispersion characteristic opposite to the slope of the dispersion characteristic received by the LFM signal.

The figure 1 shows the structure of the TAF for receiving the LFM signal of the microwave range.

The figure 2 shows the topology of the TAF of the eighth order, made on microstrip lines.

The figure 3 shows the output signal TAF

The figure 4 shows: a) a time-expanded copy of the LFM signal, with points at which delay lines are selected; b) the original signal.

The transverse analog filter for receiving the LFM signal of the microwave range contains: a power divider - 1; a set of parallel channels for signal transmission, including elementary phase circuits made in the form of segments of transmission lines - 2; power adder - 3.

The filter works as follows. The input noisy signal is fed to the input of the TAF and is divided in the power divider (made, for example, on Wilkinson bridges) into N separate copies with lower power, which are distributed over parallel channels. In each channel, the signal is delayed for a time determined by the length of the LZ. The length of the LZ is chosen so that the propagation time of the signal through each channel corresponds to the time of the appearance of local maxima of the LFM signal having a slope of the dispersion characteristic that is opposite to the slope of the dispersion characteristic received by the LFM signal, as shown in figure 4.

Where L _i is the length of the corresponding LZ, τ _i is the time of the appearance of a local maximum, V is the propagation velocity of the electromagnetic wave in the transmission line.

After the delay, the signals of all channels are added using the power adder. Thus, at the output of the TAF, a signal will be observed, defined by the expression:

where S (t) is the input signal depending on the time t, T _i is the delay time introduced by the i-th delay line, N is the number of LZs.

The signal at the output of the TAF is equivalent to the correlation of the input signal and its copy:

where h (t) is the impulse response of an ideal matched filter for a given LFM signal, but not in the entire set of signal values, but at the moments determined by the structure of the TAF:

That is, the signal standard in the TAF is set by the desired phase ratio at given times. Therefore, if the delays for TAFs are taken for a signal that is the inverse received by the LFM signal in time, then the output of the TAF is expected to incomplete convolution of the received LFM signal with itself. When sampling the input signal delays back in time to the maxima of the reference LFM signal, the signal is compressed in time with its amplitude increase, which allows to obtain the required technical result for creating a system for detecting the LFM signal in the microwave range, providing incomplete convolution of the received LFM signal with itself, as seen in figure 3.

The signal from the output of the filter is supposed to be supplied to a power detector with sufficient speed (the time constant of the detector should be no more than the length of the initial pulse of the LFM). The signal from the power detector is digitized and further processed digitally in one way or another, for example, at a predetermined threshold, already as a response from the output of a matched filter, without building a digital matched filter.

The result is the detection of the LFM signal of the microwave range due to the operation of calculating the incomplete convolution function between the received and reference LFM signal, which is accompanied by noise suppression and the formation of a signal with a pronounced maximum at the output of the TAF. The task that was posed during the development of this utility model has been solved.

In addition, the use of TAFs for receiving chirp signals will reduce the cost of radio systems that use these filters and increase the reliability of these systems by reducing the number of rations.

The operations of transferring the received signal down the spectrum, digitizing the signal transferred down the spectrum of the signal and storing the input data array for the reception interval (frame) are excluded, which makes it possible to use cheaper and simpler computing tools to process the signal or to free up computing power for other tasks.

The proposed TAF is made in the form of a printed circuit board and contains only passive components, namely, segments of microstrip lines and resistors. The resistance to an increased power level of the input signals for this filter will be determined by the electric strength of the materials used, the width of the gaps between adjacent lines and the dissipated power used in the dividers and adders of the resistors.

The use of this filter will also allow to exclude the operation of heterodyning when receiving and processing the LFM signal, to increase the frequency deviation of the used LFM signal, to switch to the use of the LFM signal with a short duration, and also to reduce the requirements for the manufacturing processes of the device for receiving and processing the signal.

Claims (1)

A transverse analog filter for receiving a microwave frequency signal of the microwave range, containing a set of channels for signal transmission, each of which contains an elementary phase circuit and is connected by its output to the input of the power adder, characterized in that the signal is supplied to each channel through a power divider, the number of channels is determined the pulse width of the chirp signal, and the elementary phase circuits are made in the form of segments of transmission lines, for example, microstrip lines, the length of which is selected so that I the signal on each channel corresponds to the time of appearance of local maxima chirp signal having a slope of the dispersion characteristics of the inverse dispersion slope received chirp signal.

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