RU2013135514A - Phase method of direction finding and phase direction finder for its implementation - Google Patents

Abstract

1. The phase direction finding method, based on receiving signals, amplifying and limiting them in amplitude, comparing signals transmitted through two channels in phase, while the signal of one of the channels is pre-phase shifted by 90 ° in phase, set n receiving antennas in the azimuth plane circles of radius d with the possibility of their electronic rotation with an angular velocity Ω around the receiving antenna, placed in the center of the circle, receive antennas are placed around the circle, alternately with frequency Ω, the signal received by the antenna is placed at the center of the circle, it is converted in frequency, the intermediate frequency voltage is isolated, it is multiplied with signals alternately received by n receiving antennas located around the circle, the phase-modulated voltage is extracted, it is multiplied with the local oscillator voltage, the low-frequency voltage is extracted with the frequency Ω and the phase is compared with a reference voltage, forming an accurate but ambiguous direction finding scale of the signal radiation source, simultaneously phase-modulated voltage is subjected to autocorrelation processing They select a low-frequency voltage with a frequency Ω, compare it in phase with the reference voltage, forming a rough but unambiguous direction finding scale for the signal source, set the second receiving antenna in the elevation plane at a distance d from the first receiving antenna, receive a signal on it, amplify and limit it in amplitude, it is multiplied with an intermediate frequency voltage, the first harmonic voltage is isolated at the local oscillator frequency, it is multiplied with a local oscillator voltage, the first low-frequency voltage is isolated

Claims (2)

1. The phase direction finding method, based on receiving signals, amplifying and limiting them in amplitude, comparing signals transmitted through two channels in phase, while the signal of one of the channels is pre-phase shifted by 90 ° in phase, set n receiving antennas in the azimuth plane circles of radius d with the possibility of their electronic rotation with an angular velocity Ω around the receiving antenna, placed in the center of the circle, receive antennas are placed around the circle, alternately with frequency Ω, the signal received by the antenna is placed at the center of the circle, it is converted in frequency, the intermediate frequency voltage is isolated, it is multiplied with signals alternately received by n receiving antennas located around the circle, the phase-modulated voltage is extracted, it is multiplied with the local oscillator voltage, the low-frequency voltage is extracted with the frequency Ω and the phase is compared with a reference voltage, forming an accurate but ambiguous direction finding scale of the signal radiation source, simultaneously phase-modulated voltage is subjected to autocorrelation processing They select a low-frequency voltage with a frequency Ω, compare it in phase with the reference voltage, forming a rough but unambiguous direction finding scale for the signal source, set a second receiving antenna in the elevation plane at a distance d ₁ from the first receiving antenna, receive a signal on it, amplify it and limit it in amplitude, multiply it with an intermediate frequency voltage, isolate the first harmonic voltage at the local oscillator frequency, multiply it with a local oscillator voltage, isolate the first low-frequency voltage proportional to the phase difference between the signals received by the first and second receiving antennas, forming a rough but unambiguous direction finding scale for the signal source in the elevation plane, characterized in that a third receiving antenna is installed in the elevation plane at a distance of d ₁ from the second receiving antenna on one lines with it, receive a signal on it, amplify and limit it in amplitude, multiply it with an intermediate frequency voltage, emit a second harmonic voltage at the heterodyne frequency a, multiply it with the local oscillator voltage, isolate a second low-frequency voltage proportional to the phase difference between the signals received by the first and third receiving antennas, forming an accurate but ambiguous direction finding scale of the radiation source in the elevation plane, record the first and second low-frequency voltages, multiply the first and second harmonic voltages at the local oscillator frequency, measure the difference of the phase differences, determine the range and altitude of the aircraft on board which placed the source of the signal radiation, register them. 2. A phase direction finder comprising a first receiving antenna in series, a first receiver, a mixer, the second input of which is connected to the local oscillator output, an intermediate frequency amplifier, a first multiplier, a first bandpass filter, a delay line, a second phase detector, the second input of which is connected to the output of the first band-pass filter, the first phase shifter 90 °, the first phase detector, the second input of which is connected to the second output of the reference oscillator, and an indicator, the reference oscillator connected in series, the generator a pulse torus, an electronic switch, n inputs of which are connected to the outputs of n receiving antennas arranged around a circle of radius d with the possibility of electronic rotation around the first receiving antenna located in the center of the circle, and a second receiver, the output of which is connected to the second input of the first multiplier, connected in series to the output of the first bandpass filter, a second multiplier, the second input of which is connected to the output of the local oscillator, a second bandpass filter and a third phase detector, the second input of which is connected to the third output of the reference generator, and the output is connected to the second input of the indicator, the second receiving antenna, the third receiver, the third multiplier, the second input of which is connected to the output of the intermediate frequency amplifier, the third pass filter and the fourth phase detector, the second input of which is connected to the local oscillator output , the second receiving antenna mounted in the elevation plane at a distance d ₁ from the first receiving antenna, characterized in that it comprises a third receiving antenna, fourth etc. a receiver, a fourth and fifth multiplier, a fourth bandpass filter, a fifth phase detector, a phase meter and a computing unit, and a fourth receiver, a fourth multiplier, the second input of which is connected to the output of the intermediate frequency amplifier, a fourth bandpass filter and a fifth phase one, are connected in series to the output of the third receiving antenna a detector, the second input of which is connected to the output of the local oscillator, and the output is connected to the third input of the indicator, the fourth input of which is connected to the output of the fourth phase a detector, the fifth multiplier is connected to the output of the third bandpass filter, the second input of which is connected to the output of the fourth bandpass filter, a phase meter and a computing unit, the second and third inputs of which are connected to the outputs of the fourth and fifth phase detectors, respectively, and the output is connected to the fifth input of the indicator, the third receiving antenna is installed in the elevation plane at a distance d ₁ from the second receiving antenna in line with it.