RU215748U1 - MATCHED FILTER - Google Patents

Abstract

The utility model relates to the field of radio engineering and can be used in synchronization systems of radio systems of various profiles. EFFECT: enabling processing of a sixty-bit sequence of the form "010101101101010010010010101101101101101101101101010101101010". For this, thirteen phase shifters are additionally introduced into the matched filter, which makes it possible to obtain a non-periodic and periodic autocorrelation function, the main lobe of which has a width of two clock pulses, and the side lobes are equal to zero, by providing a method for processing a sixty-bit sequence of the form “010101101101010010010010 10110110110101010101010101010101010101010101010101010101010110110101010101010101010101010101010101010101010101010101010. 5 ill.

Description

The utility model relates to the field of radio engineering and can be used in synchronization systems of radio systems of various profiles operating in a difficult interference environment, while providing reception with a sixty-bit sequence of the form "010101101101010010010010101101101101101101101101010101101010".

A device for processing phase-code-keyed signals according to the Barker code is known, containing a filter, a multi-tap delay line, M phase shifters, an adder, and the filter input is the input of the device, and the filter output is connected to the input of the M-th phase shifter and to 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 M-th phase shifter is also connected, and the output of the adder is the output of the device (Baskakov S.I. Radio engineering circuits and signals: textbook for universities on the special "Radio engineering" / S.I. Baskakov - 3rd edition revised and additional - M .: Higher school, 2000, p. 428).

The technically closest solution is 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, twenty-one phase shifters and an adder, with three phase shifters connected, respectively, to the fifty-ninth output of the delay line, the fifty-eighth delay line output, the fifty-seventh delay line output, twelve phase shifters are connected, respectively, to the forty-seventh delay line output, the forty-sixth delay line output, the forty-fifth delay line output, the forty-fourth delay line output, the forty-third delay line output, the forty-second output delay line, the forty-first delay line output, the fortieth delay line output, the thirty-ninth delay line output, the thirty-eighth delay line output, the thirty-seventh delay line output, the thirty-sixth delay line output, three phase shifters are connected, respectively, to the eleventh delay line output, the tenth delay line output, the ninth delay line output, two phase shifters are connected respectively to the second delay line output, the first delay line output, one phase shifter is connected to the output of the auxiliary filter, and the output of the auxiliary filter in parallel with the tapped delay line is connected to the adder , to which all outputs from the delay line are also connected (RF patent No. 208231, 2021).

The disadvantage of these devices is that they accept only one numerical sequence, that 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 two clock pulses, and the side lobes are equal to zero.

The technical objective of the utility model is to extend the functionality of the matched filter, allowing to obtain a non-periodic and periodic autocorrelation function, the main lobe of which has a width of two clock pulses, and the side lobes are equal to zero, by providing a method for processing a sixty-bit sequence of the form "01010110110101001001001010110110110110110110110101010110101010101010101010101010101010101010010010101101010101010101010101010101010100100100101011011011011010101010101".

The essence of the utility model lies in the fact that in 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, twenty-seven phase shifters and an adder, with one phase shifter connected, respectively, to the fifty-ninth output of the delay line, one phase shifter is connected, respectively, to the fifty-seventh output of the delay line, one phase shifter is connected, respectively, to the fifty-fifth output of the delay line, one phase shifter is connected, respectively, to the fifty-second output of the delay line, one phase shifter is connected, respectively, to the forty-ninth output of the line delay, one phase shifter is connected, respectively, to the forty-seventh output of the delay line, two phase shifters are connected, respectively, to the forty-fifth output of the delay line, the forty-fourth output of the delay line, two phase shifters are connected, respectively, to the forty-second output of the delay line, the forty-first outputdelay lines, two phase shifters connected respectively to the thirty-ninth delay line output, thirty-eighth delay line output, one phase shifter connected, respectively, to the thirty-sixth delay line output, one phase shifter connected, respectively, to the thirty-fourth delay line output, one phase shifter connected, respectively, to the thirty-first output of the delay line, one phase shifter is connected, respectively, to the twenty-eighth output of the delay line, one phase shifter is connected, respectively, to the twenty-fifth output of the delay line, one phase shifter is connected, respectively, to the twenty-second output of the delay line, one phase shifter is connected, respectively, to the nineteenth output of the delay line, one phase shifter is connected, respectively, to the sixteenth output of the delay line, one phase shifter is connected, respectively, to the thirteenth output of the delay line, one phase shifter is connected, respectively, to the eleventh output delay lines, one phase shifter is connected, respectively, to the ninth output of the delay line, one phase shifter is connected, respectively, to the seventh output of the delay line, one phase shifter is connected, respectively, to the fourth output of the delay line, one phase shifter is connected, respectively, to the second output of the delay line , one phase shifter is connected at the output of the auxiliary filter, and the output of the auxiliary filter is connected in parallel with the multi-tap delay line to the adder, to which all outputs from the delay line are also connected.

The novelty lies in the fact that the matched filter provides the possibility of processing a signal represented by a sixty-bit sequence of the form "010101101101010010010010101101101101101101101101010101101010" due to the additional introduction of thirteen phase shifters on certain taps of the delay line.

In FIG. 1 shows an electrical block diagram of a matched filter for receiving a sixty-bit sequence like "010101101101010010010010101101101101101101101101010101101010".

In FIG. 2 shows a non-periodic autocorrelation function of a discrete sixty-bit sequence.

In FIG. 3 shows the periodic autocorrelation function of a discrete sixty-bit sequence (two repetitions).

In FIG. 4 shows the non-periodic autocorrelation function of a phase-shift keyed sixty-bit sequence.

In FIG. 5 shows the periodic autocorrelation function of a phase-shift keyed sixty-bit sequence (two repetitions).

The matched filter shown in Fig. 1, contains an auxiliary filter 1, the input of which is the input of a matched filter, and its output is the input of the delay line 2, twenty-seven phase shifters 3.1 ... 3.27 and an adder 4, and the phase shifter 3.1 is connected to the output of the auxiliary filter 1, the phase shifter 3.2 is connected to the second line output delay, phase shifter 3.3 is connected to the fourth output of the delay line, phase shifter 3.4 is connected to the seventh output of the delay line, phase shifter 3.5 is connected to the ninth output of the delay line, phase shifter 3.6 is connected to the eleventh output of the delay line, phase shifter 3.7 is connected to the thirteenth output of the delay line, phase shifter 3.8 is connected to the sixteenth output of the delay line, the phase shifter 3.9 is connected to the nineteenth output of the delay line, the phase shifter 3.10 is connected to the twenty-second output of the delay line, the phase shifter 3.11 is connected to the twenty-fifth output of the delay line, the phase shifter 3.12 is connected to the twenty-eighth output of the delay line, the phase shifter 3.13 is connected to the thirty-first output of the delay line, phase shifter 3.14 is connected to the thirty-fourth output of the delay line, phase shifter 3.15 is connected to the thirty-sixth output of the delay line, phase shifter 3.16 is connected to the thirty-eighth output of the delay line, phase shifter 3.17 is connected to the thirty-ninth output of the delay line, phase shifter 3.18 is connected to the forty-first output of the delay line, phase shifter 3.19 is connected to the forty-second output of the delay line, phase shifter 3.20 is connected to the forty-fourth output of the delay line, phase shifter 3.21 is connected to the forty-fifth output of the delay line, phase shifter 3.22 is connected to the forty-seventh output of the delay line, phase shifter 3.23 is connected to the forty-ninth output of the delay line, phase shifter 3.24 is connected to the fifty-second output of the delay line, phase shifter 3.25 is connected to the fifty-fifth output of the delay line, phase shifter 3.26 is connected to the fifty-seventh output of the delay line, phase shifter 3.27 p Connected to the fifty-ninth output of the delay line.

The principle of operation of the device is that the input of the auxiliary filter 1 receives a sequence of segments of harmonic oscillations. At the output of the auxiliary filter 1, under the influence of the input delta pulse, a radio pulse appears with a rectangular envelope. This pulse is applied to delay line 2 with taps. A rectangular radio pulse, moving along the delay line 2, and, depending on the tap number from the delay line, passing through the phase shifters 3.1-3.27 alternately excites the inputs of the adder 4. At each cycle of the circuit in the adder 4, the received signals are summed. The summation result is the basis for making a decision about the presence or absence of a signal in the delay line 2.

The total duration of the delay line 2 with taps is 59τ ₀ , while the signal delay between each two adjacent taps is τ ₀ .

Phase shifters 3.1-3.27 provide a phase rotation of the segment of the harmonic oscillation entering their input by 180°.

The adder 4 for sixty 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 3.1-3.27.

The set of delay line 2 with taps and phase shifters 3.1-3.27 is a "frozen" desired sixty-bit sequence. Therefore, sequentially arriving phase-shift keyed pulses of a sixty-bit sequence from the output of the auxiliary filter 1 to the input of the delay line 2 will be added in the adder 4 into a common harmonic oscillation. In this case, the envelope of the general harmonic oscillation will display the autocorrelation function of this discrete sixty-bit sequence from cycle to cycle. When the fifty-ninth pulse arrives at the delay line 2 with taps, and the sixtieth pulse arrives at the adder 4, all phase-shift keyed pulses of the sixty-bit sequence will add up in the adder 4 in phase over one period into a common harmonic oscillation, which will correspond to the autocorrelation peak of this discrete sixty-bit sequence. Further advancement of the phase-shift keyed pulses of the desired sequence along the delay line 2 with taps will lead to a decrease in the number of pulses added in the adder 4, and the envelope of their sum from cycle to cycle will also display the autocorrelation function of this discrete sixty-bit sequence.

The autocorrelation function of a discrete sixty-bit sequence in non-periodic mode has the form shown in Fig. 2. Its distinctive feature is that the duration of the main lobe is 2 τ ₀ . However, the autocorrelation function of the discrete sixty-bit sequence in the presence of two repetitions has the form shown in Fig. 3. From FIG. 3 it follows that in the periodic mode, the autocorrelation function of the sixty-bit sequence has side lobes equal to zero, which is not the case for any of the known discrete sequences.

When a single repetition of such a sequence is received at the input of the matched filter, the autocorrelation function of the phase-shift keyed sixty-bit sequence will be obtained at the output of the matched filter, which is shown in Fig. 4. Note that this autocorrelation function is non-periodic. When two repetitions of such a sequence are received at the input of the matched filter, the autocorrelation function of the phase-shift keyed sixty-bit sequence will be obtained at the output of the matched filter, which is shown in Fig. 5. Note that this autocorrelation function has a period with zero side lobes and is a periodic autocorrelation function over their duration.

Thus, the proposed matched filter allows you to implement functions not provided by the prototype, namely, to obtain a non-periodic and periodic autocorrelation function, the main lobe of which has a width of two clock pulses, and the side lobes are equal to zero, by providing a method for processing a sixty-bit sequence of the form "01010110110101001001001010110110110110101010101" .

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, fourteen phase shifters, and one phase shifter is connected, respectively, to the second output of the delay line, one phase shifter is connected, respectively, to the ninth output of the delay line, one the phase shifter is connected, respectively, to the eleventh output of the delay line, one phase shifter is connected, respectively, to the thirty-sixth output of the delay line, two phase shifters are connected, respectively, to the thirty-eighth and thirty-ninth outputs of the delay line, two phase shifters are connected, respectively, to the forty-first and the forty-second delay line outputs, two phase shifters are connected, respectively, to the forty-fourth and forty-fifth delay line outputs, one phase shifter is connected, respectively, to the forty-seventh delay line output, one phase shifter is connected, respectively, to the fifty-seventh delay line output and, an adder, wherein the output of the auxiliary filter is connected in parallel to the multi-tap delay line to the adder, to which all outputs from the delay line are also connected, characterized in that an additional thirteen phase shifters are introduced into it, with one phase shifter connected, respectively, to the fifty-fifth output of the delay line , one phase shifter is connected, respectively, to the fifty-second output of the delay line, one phase shifter is connected, respectively, to the forty-ninth output of the delay line, one phase shifter is connected, respectively, to the thirty-fourth output of the delay line, one phase shifter is connected, respectively, to the thirty-first output delay line, one phase shifter is connected, respectively, to the twenty-eighth delay line output, one phase shifter is connected, respectively, to the twenty-fifth delay line output, one phase shifter is connected, respectively, to the twenty-second delay line output, one phase shifter is connected, respectively respectively, to the nineteenth delay line output, one phase shifter is connected, respectively, to the sixteenth delay line output, one phase shifter is connected, respectively, to the thirteenth delay line output, one phase shifter is connected, respectively, to the seventh delay line output, one phase shifter is connected, respectively, to the fourth output of the delay line.

Images