RU176645U1 - AGREED FILTER - Google Patents

Abstract

The objective of the utility model is to expand the functionality by providing the possibility of receiving a twenty-bit sequence of the form “10011100011111111100” and issuing a periodic and non-periodic autocorrelation function to this sequence. A sequence of segments of harmonic oscillations is fed to filter 1. At the output of this filter, a radio pulse appears under the influence of an input delta pulse with an envelope of rectangular shape. This pulse is applied to delay line 2 with taps. A rectangular radio pulse moving along the delay line 2, and, depending on the number of taps from the delay line, passing through the phase shifters 3.1 - 3.7 alternately excites the inputs of the adder 4. Then, the received signals are summed. Based on the result of the summation, a decision is made on the presence or absence of a signal.

Description

The utility model relates to the field of radio engineering and can be used in synchronization systems of radio systems of various profiles.

A device for processing phase-code-manipulated signals according to the Barker code, comprising a filter, a multi-tap delay line, M phase shifters, an adder, the filter input being the input of the device, and the filter output connected to the input of the Mth phase shifter and the input of the multi-tap delay line, M -1 outputs of which are connected to each of the M-1 phase shifters, which in turn are connected to the input of the adder, to which the output of the Mth phase shifter is also connected, and the output of the adder is the output of the device (Baskakov S.I. Radotekhniches .. S circuits and signals: Textbook for high schools on special "Radio" / SI Baskakov - 3rd ed rev and Sub-M .: Higher wk, 2000)......

The disadvantage of the analogue is limited functionality, expressed in the impossibility of obtaining a non-periodic and periodic autocorrelation function, the main lobe of which has a width of four clock pulses, and the side lobes are zero.

The closest in technical essence solution is the Barker signal processing device when it is detected, containing an auxiliary filter, the input of which is the input of the device, and its output is the input of the delay line, from the 1st to the Nth adders, which implement the summing operation modulo 2, the second inputs of which are connected respectively to the outputs of the 1st, 2nd, ..., Nth elements of the reference signal, the outputs from the 1st to Nth adders implementing the summing operation modulo 2 are connected respectively to the inputs from the 1st by Nth invert s, an adder whose output is the output of the device, from the 1st to the Nth switches, from the 1st to the Nth bandpass filters, from the 1st to the Nth dispersion delay lines, from the 1st to N- phase shifters, while the input of the first switch is connected to the output of the auxiliary filter, and the inputs from the 2nd to the Nth switches are connected to the corresponding outputs of the delay line, the first outputs from the 1st to the Nth switches are connected respectively to the first inputs from 1 on the Nth adders implementing the summation operation modulo 2, and the second outputs are connected respectively with inputs from the 1st to the Nth bandpass filters, the outputs of which are respectively the inputs from the 1st to the Nth dispersion delay lines, the outputs of which are connected respectively from the 1st to the Nth inverters, while the outputs from 1 of the Nth inverters are connected respectively to the inputs from the 1st to the Nth phase shifters, the outputs of which are connected to the inputs of the adder (RU No. 132570, publ. 09/20/2013).

The disadvantage of the prototype is the redundancy of the elemental base and limited functionality, expressed in the impossibility of obtaining a non-periodic and periodic autocorrelation function, the main lobe of which has a width of four clock pulses, and the side lobes are zero.

The objective of the utility model is to expand the functionality of the prototype by providing the possibility of receiving a twenty-bit sequence of the form “10011100011111111100” and obtaining a non-periodic and periodic autocorrelation function, the main lobe of which has a width of four clock pulses, and the side lobes are zero.

The essence of the utility model is that in a matched filter containing an auxiliary filter, the input of which is the input of the matched filter, and its output is the input of the delay line, seven phase shifters and an adder are introduced, the first phase shifter connected to the eighteenth output of the delay line, the second phase shifter to seventeenth delay line output, third phase shifter to thirteenth delay line output, fourth phase shifter to twelfth delay line output, fifth phase shifter to eleventh at the output of the delay line, the sixth phase shifter is connected to the first output of the delay line, and the seventh phase shifter is connected to the output of the auxiliary filter in parallel with the multi-tap delay line, the output of which is connected to the adder, to which all outputs from the delay line are also connected.

The novelty is that the matched filter provides a non-periodic and periodic autocorrelation function, the main lobe of which has a width of four clock pulses, and the side lobes are zero due to the introduction of seven phase shifters at specific taps of the delay line and adder.

In FIG. 1 shows an electrical block diagram of a matched filter for receiving a twenty-bit sequence of the form “1001110001111111111100”.

In FIG. 2 (a) shows a time view of a twenty-bit sequence.

In FIG. 2 (b) shows a twenty-bit sequence in the form of a phase-shift oscillation.

In FIG. 3 shows the autocorrelation function of a discrete twenty-bit sequence in a non-periodic mode.

In FIG. 4 shows the autocorrelation function of a discrete twenty-digit sequence in the presence of three repetitions.

In FIG. 5 depicts the non-periodic autocorrelation function of a phase-manipulated twenty-bit sequence.

In FIG. Figure 6 shows the periodic autocorrelation function of a phase-manipulated twenty-bit sequence in the presence of three repetitions.

The matched filter contains an auxiliary filter 1, the input of which is the input of the matched filter 1, and its output is the input of the delay line 2, seven phase shifters 3.1 ... 3.7 and the adder 4, and the phase shifter 3.1 is connected to the eighteenth output of the delay line 2, the phase shifter 3.2 to the seventeenth output delay line 2, phase shifter 3.3 - to the thirteenth output of delay line 2, phase shifter 3.4 - to the twelfth output of delay line 2, phase shifter 3.5 - to the eleventh output of delay line 2, phase shifter 3.6 - to the first output of the line behind holding 2, and to the output of the auxiliary filter 1 in parallel to the multi-tap delay line 2, a phase shifter 3.7 is connected, the output of which is connected to the adder 4, to which all outputs from the delay line 2 are also connected.

The matched filter works as follows.

The twenty-bit sequence has the time view shown in FIG. 2 (a). In this case, single symbols are represented by positive pulses of duration τ ₀ , and zero symbols are represented by negative pulses of the same duration. At the input of the matched filter, the twenty-bit sequence arrives in the form of a phase-shift oscillation of FIG. 2 (b), and single symbols correspond to one period of harmonic oscillation with an initial phase equal to 0 °, and zero symbols correspond to one period of harmonic oscillations with an initial phase equal to 180 °. The auxiliary filter 1 is designed for the frequency separation of the phase-manipulated twenty-bit sequence from the set of received radio frequency signals of the ether.

The total duration of the delay line 2 with taps is 19 τ ₀ , while the delay of the signals between each two adjacent taps is τ ₀ .

Phase shifters 3.1-3.7 provide phase rotation of the segment of harmonic oscillations entering their input by 180 °.

An adder 4 to twenty inputs provides the addition of segments of harmonic oscillations available both at the outputs of the delay line 2 and at the outputs of the phase shifters 3.1-3.7.

The set of delay line 2 with taps and phase shifters 3.1-3.7 is a “frozen” desired twenty-bit sequence. Therefore, the phase-manipulated pulses of a twenty-bit sequence successively arriving from the output of the auxiliary filter 1 to the input of the delay line 2 with taps and the phase shifter 3.7 will add up to total harmonic oscillation in adder 4. In this case, the envelope of the general harmonic oscillation will from time to time display the autocorrelation function of this discrete twenty-bit sequence. When a nineteenth pulse arrives at delay line 2 with taps, and a twenty pulse arrives at phase shifter 3.7, all phase-manipulated pulses of a twenty-bit sequence will add up in the totalizer 4 in a single period to a single harmonic oscillation, which will correspond to the autocorrelation peak of this discrete twenty-bit sequence. Further advancement of phase-shifted pulses of the desired sequence along the delay line 2 with taps will lead to a decrease in the number of 4 pulses added in the adder, and the envelope of their sum from clock to clock will also display the autocorrelation function of this discrete twenty-bit sequence.

The autocorrelation function of a discrete twenty-bit sequence in a non-periodic mode has the form shown in FIG. 3. Its distinctive feature is that the duration of the main lobe is 4 τ ₀ , with respect to the duration 2 τ ₀ , which have the basic, currently known discrete sequences (for example, M-sequences, Barker sequences, etc.). However, the autocorrelation function of a discrete twenty-bit sequence in the presence of three repetitions has the form shown in FIG. 4. From the figure in FIG. 4 it follows that in the periodic mode the autocorrelation function of a twenty-bit sequence has side lobes equal to zero, which is not found in any of the known discrete sequences.

Upon receipt of one repeat of such a sequence at the input of the matched filter, the autocorrelation function of the phase-manipulated twenty-bit sequence will be obtained at the output of the matched filter, which is shown in FIG. 5. Note that this autocorrelation function is non-periodic.

Upon receipt of three repetitions of such a sequence at the input of the matched filter, the autocorrelation function of the phase-manipulated twenty-bit sequence will be obtained at the output of the matched filter, which is shown in FIG. 6. Note that this autocorrelation function has two periods with zero side lobes and for their duration is a periodic autocorrelation function.

Thus, the proposed matched filter allows you to implement functions not provided by the prototype, and can be made on a known elemental base and well-known industrial means.

Claims (1)

A matched filter containing an auxiliary filter, the input of which is the input of the device, and its output is the input of the delay line, characterized in that seven phase shifters and an adder are introduced into it, the phase shifters being connected to the eighteenth output of the delay line, the seventeenth output of the delay line, the thirteenth output of the line delay, the twelfth output of the delay line, the eleventh output of the delay line, the first output of the delay line, and to the output of the auxiliary filter parallel to the multi-tap delay line p A phase shifter is connected, the output of which is connected to the adder, to which all outputs from the delay line are also connected.

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