RU145995U1 - PHASE RADIO DETECTOR - Google Patents

Abstract

A phase direction finder comprising at least two direction-finding antenna elements interconnected, signal amplifiers, a phase detector and a computer, characterized in that the outputs of direction-finding antenna elements are connected to the inputs of a switching matrix, the outputs of which are connected to the phase detector through signal amplifiers, which is connected with a computer that compensates for non-identities of the phase characteristics of the receiver channels and controls the state of the switching matrix.

Description

The utility model relates to the field of radio engineering and can be used to construct phase systems for determining angular coordinates, the principle of which is based on determining the phase shift between radio signals from two direction finding antennas.

Known radio direction finder (RU 2309421, publ. 10.27.2007, G01S 3/48) containing direction-finding antenna elements, receivers, phase detectors, logic processing units for measuring bearings. The direction finder compensates for the non-identical phase characteristics of the receiving channels through the use of a sinusoidal calibration signal generated by the calibration generator. A calibration table of phase shifts is formed, the values of which are used to compensate for the non-identical phase characteristics.

The advantage of this device is to increase the accuracy of bearing measurement through the use of a system to eliminate the non-identical characteristics of the receiver channels.

The disadvantage of this device is the need for re-calibration when replacing elements, the need to store calibration coefficients, i.e. the complexity of the design of the receiver.

Closest to the claimed utility model is a multi-channel direction finder (RU 2096797, publ. 20.11.1997, G01S 3/14, G01S 3/74) containing direction-finding antenna elements, amplifiers of the received signals, phase detector, unit for calculating the value of the bearing.

To eliminate the non-identity of the phase characteristics of the receiving channels in this direction finder, two reception channels, signal and reference, are organized by means of which calibration values are measured. During operation of the direction finder, the obtained calibration coefficients are used to compensate for the non-identities of the phase characteristics of the reception channel.

The advantage of this device is the increased accuracy of the bearing measurement, by eliminating the influence of the non-identical channels of the receiving paths.

The disadvantage of this device is the complexity of the device, due to the introduction of an additional antenna element and an additional receiving path

The problem to which the claimed utility model is directed is to reduce the bearing calculation error by compensating for the phase non-identity of the receiver channels without increasing the number of antenna elements.

The solution to this problem is achieved due to the fact that the direction finder contains at least two direction-finding antenna elements interconnected, signal amplifiers, a phase detector and a computer, while the outputs of the direction-finding antenna elements are connected to the inputs of a switching matrix, the outputs of which are connected to the phase detector through signal amplifiers, which is connected to a computer that compensates for non-identities of the phase characteristics of the receiver channels and controls the state of the switching matrix.

The technical result of the utility model is to reduce the measurement error of the bearing by automatically compensating for the non-identity of the receiver channels in a wide frequency range without using an additional reference antenna element and the reference channel of the receiver.

The device shown in the figure contains direction-finding antenna elements 1 and 2, a switching matrix 3, amplifiers of the received radio signal 4 and 5, a phase detector 6, a computer 7.

The outputs of the direction-finding antenna elements 1 and 2 are connected to the switching matrix 3. The outputs of the switching matrix 3 are connected to the phase detector 6 through signal amplifiers 4 and 5. The output of the phase detector 6 is connected to the calculator 7.

The device proposed in this application works as follows. Processing the received signal takes place in two stages.

At the first stage, the antenna elements 1 and 2 receive a signal from a radio emission source (IRI) with a wavelength of λ. The position of the switches by the switching matrix 3 is set so that the input 1 ′ is connected to the output 1 ″, and the input 2 ′ is connected to the output 2 ″.

Passing through amplifiers 4 and 5, the received signal is fed to phase detector 6. Phase detector 6 detects the phase difference of the signals received by direction-finding antenna elements:

where Δφ ₁₂ is the phase difference of the signals received by direction-finding antenna elements 1 and 2, calculated in the first stage;

d is the distance between the direction-finding antenna elements 1 and 2;

λ is the wavelength of the received signal;

ψ _i - spurious phase incursion of the i-th antenna element, i = 1,2.

In the calculator 7, the obtained value A is stored (p ₁₂ , and a control signal is supplied to the switching matrix to change the state of the switches.

At the second stage, the antenna elements 1 and 2 receive a signal from a radio emission source (IRI) with a wavelength of λ. The position of the switches by the switching matrix 3 is set so that the input 1 ′ is connected to the output 2 ″, and the input 2 ′ is connected to the output 1 ″.

Passing through amplifiers 4 and 5, the received signal is fed to phase detector 6. Phase detector 6 detects the phase difference of the signals received by direction-finding antenna elements:

where Δφ ₂₁ ^_ the phase difference of the signals received by direction-finding antenna elements 1 and 2, calculated in the second stage;

d is the distance between the direction-finding antenna elements 1 and 2;

λ is the wavelength of the received signal;

ψ _i - spurious phase incursion of the i-th antenna element, i = 1,2.

In the calculator 7, the obtained value Δφ _{21 is} stored and the procedure for compensating parasitic phase incursions according to formula (3) is performed.

Based on the obtained adjusted value of the phase difference, the estimate for the IRI bearing is calculated, in the simplest version according to the formula (4):

Thus, the claimed device in comparison with the known device (prototype) allows for automatic compensation of non-identities of the receiver channels, eliminating their spurious effect on the accuracy of measuring the phase difference, and thereby improve the accuracy of measuring bearings on the IRI in a wide frequency range.

Claims (1)

A phase direction finder comprising at least two direction-finding antenna elements interconnected, signal amplifiers, a phase detector and a computer, characterized in that the outputs of direction-finding antenna elements are connected to the inputs of a switching matrix, the outputs of which are connected to the phase detector through signal amplifiers, which is connected with a computer that compensates for non-identities of the phase characteristics of the receiver channels and controls the state of the switching matrix.