RU94723U1 - RADAR SURVEILLANCE STATION - Google Patents

Abstract

 A continuous-wave radar survey station, including a probe signal generator with a periodic phase change, a continuous oscillator, an antenna, a circulator, a low-noise amplifier, a quadrature mixer, a matched filter, while the output of the reference oscillator is connected to the input of the probe signal shaper, the circulator output connected to the input of a low-noise amplifier, the output of a low-noise amplifier is connected to the input of a quadrature mixer, characterized in that in it Two identical radio signal splitters, N-1 circulators, N-1 low-noise amplifiers, N-1 quadrature mixers, two identical N-input signal adders, were introduced separately, and the antenna is made in the form of an N-element antenna array, while the input of the first radio signal splitter is connected with the output of the probe signal generator, and its outputs are connected to the first inputs of the circulators, the input of the second splitter of radio signals is connected to the output of the continuous reference oscillator, and its outputs are connected to the first inputs of the quad mixer, and the output of each of the elements of the antenna array is connected to the second input of the corresponding circular, and the output of each of the circulators is connected to the input of the corresponding low-noise amplifier, the outputs of each of which are connected to the second input of the corresponding quadrature mixer, and the I-outputs of each of the quadrature mixers are connected with the inputs of the N-input first signal adder, and the Q-outputs of each of the quadrature mixers are connected to the inputs of the second signal adder, and the outputs of the first and W

Description

The utility model relates to radar and can be used for remote detection of small objects (objects with a small value of the effective scattering surface), as well as in the field of altimeter.

Known radar survey station with continuous radiation (Bakulev PA Radar systems. A textbook for high schools. - M .: Radio engineering 2004, p. 233-234), which contains a shaper of a probing signal with a periodic phase change, a reference generator of continuous oscillation , antenna, circulator, low noise amplifier (LNA), quadrature mixer, matched filter. The output of the reference generator is connected to the input of the probe driver, the output of the circulator is connected to the input of the low-noise amplifier, the output of the low-noise amplifier is connected to the input of the quadrature mixer.

The disadvantage of this device is its low energy potential.

A device is known that we selected for the prototype (Bakulev PA Radar systems. A textbook for high schools. - M .: Radio engineering 2004, pp. 233-234), which can be implemented in a single-antenna version. In this case, instead of the second antenna, a circulator is used, which switches one antenna to transmit and receive. The device consists of a probe signal generator, from which the modulated radio signal is fed to the input of the circulator. From the output of the circulator, the signal enters the antenna with a narrow radiation pattern and is radiated into space. The reflected signal from objects "falling" into the antenna radiation pattern is received by the same antenna through the circulator and fed to the input of a low-noise amplifier, and from its output the signal is fed to the input of a quadrature mixer, the reference oscillation of which is a generator signal with a frequency of ω ₀ . At the output of the quadrature mixer, a complex envelope of the reflected signal is formed in the form of quadrature components I and Q. Components I and Q are fed to the input of the matched filter, in which the complex envelope of the reflected signal is matched with the emitted signal, and a response proportional to the output of the matched filter module of the mutual correlation function of the emitted and reflected signals. The output response of the filter allows you to evaluate the range and reflectivity (EPR) of objects located in the field of view of the radar station.

The main disadvantage of this device is that the energy potential is limited due to the irremovable penetration of the emitted continuous signal to the input of the receiver, which, in turn, limits its use, for example, when solving the problem of radar sensing of small objects (objects with a small value of the effective scattering surface) . When the radiation power is increased, the moment comes when the parasitic penetration of the emitted signal to the LNA input overloads the receiving path, which disrupts the operation of the device.

The main technical problem solved by the proposed utility model is to create a device that can increase the radar energy potential.

The problem is achieved in that in a continuous-wave radar survey station, which includes a probe signal generator with a periodic phase change, a continuous oscillator, an antenna, a circulator, a low-noise amplifier, a quadrature mixer, a matched filter, the output of the reference oscillator is connected to the input of the driver probe signal, the output of the circulator is connected to the input of a low-noise amplifier, the output of a low-noise amplifier is connected to the input of a quadrature mixer, with According to the proposed solution, two identical radio signal splitters, N-1 circulators, N-1 low-noise amplifiers, N-1 quadrature mixers, two identical N-input signal combiners, and the antenna are made in the form of an N-element antenna array, with an input the first splitter of the radio signals is connected to the output of the shaper of the probe signal, and its outputs are connected to the first inputs of the circulators, the input of the second splitter of the radio signals is connected to the output of the reference continuous oscillator, and the output its s are connected to the first inputs of the quadrature mixers, the output of each of the elements of the antenna array is connected to the second input of the corresponding circular, and the output of each of the circulators is connected to the input of the corresponding low-noise amplifier, the outputs of each of which are connected to the second input of the corresponding quadrature mixer, the outputs of each of the quadrature mixers are connected to the inputs of the N-input first signal adder, and the Q-outputs of each of the quadrature mixers are connected to the inputs of the second signal math, and the outputs of the first and second signal adders are connected to the inputs I and Q of the matched filter.

The proposed device has differences from the closest analogues, therefore, the solution satisfies the condition of patentability of the invention of "novelty."

The figure shows a functional diagram of a radar surveillance station.

The device comprises a probe signal generator 1 with a periodic phase change, the input of which is connected to the output of the continuous reference oscillator 2, and the output of the probe signal generator 1 is connected to the input of the first radio signal splitter 3, the outputs of which are connected to the inputs of the circuits 4.

The output of the reference generator 2 is connected to the input of the second splitter of the radio signal 5, the outputs of which are connected to the first inputs of the quadrature mixers 6. The output of each of the antenna elements of the antenna array 7 is connected, respectively, to the second input of the corresponding circulator 4. The third output of each circulator 4 is connected to the input of the corresponding low-noise amplifier 8. The output of each low-noise amplifier 8 is connected to the second input of the corresponding quadrature mixer 6, the I-outputs of the quadrature mixers 6 are connected to the corresponding the existing inputs of the N-input first adder of signals 9, Q-outputs of quadrature mixers 6 are connected to the corresponding inputs of the second adder of signals 10, the outputs of the first and second adders of signals 9 and 10 are connected to the inputs I and Q of the matched filter 11.

Radar surveillance station operates as follows. The probe signal generator 1 generates a modulated radio signal s ₀ (t), which is fed through the first radio signal splitter 3 to the input of the circulators 4. The probe signal is generated by modulating the phase of the reference oscillation with frequency ω ₀ generated by the reference generator 2. The probe signal is emitted in the form of a narrow beam single-channel electromagnetic "beam".

Narrowly directed radiation of the signal is carried out along N spatially distributed weakly directed channels using N weakly directed identical antenna arrays 7, which are distributed in space in such a way that when they are in-phase excited by a probing signal with a frequency of ω ₀ , whose power is distributed across N channels, a narrow radiation pattern is formed In this case, the well-known principle of constructing phased antenna arrays consisting of a finite number of antenna elements is used (Active ph ized arrays / Ed D.I.Voskresenskogo and A.I.Kanaschenkova, Izd "Radio", 2004. -. 488 s).

The reflected signal is received over N spatially distributed channels identical to the radiation channels. Reception of the reflected signal is made by each of the N weakly directed antenna arrays 7. Separation of the excitation channels of the antenna 7 and the reception of signals is realized by using a circulator 4. In each of the N reception channels, a complex envelope of the output signal of the LNA 8 is formed, for example, by moving its frequency down to the value of ω ₀ using a quadrature mixer 6. The complex envelope in each of the receiving channels is formed in the form of two quadrature signal components I (real part) and Q (imaginary part).

The received signal is generated as the sum of N complex envelopes formed in the reception channels by separately summing the I and Q components by adders 9 and 10, respectively. With identical (in-phase) weakly directed receiving channels, in-phase addition of complex envelopes will occur only for objects located in a narrow sector identical to the radiation sector, i.e. the radiation pattern for the generated received signal will be as narrow as for the emitted signal, and identical to the radiation pattern when the signal is emitted.

Consistent filtering of the received signal in the matched filter 11 is performed by calculating the generalized function of the mutual correlation of the probing and received signals. In practice, consistent filtering is implemented by converting the quadrature components of the received signal to digital form and calculating a two-dimensional convolution (according to the parameters of the time and frequency shift) of the received and emitted signals presented in digital form. As a result, the radar response is formed in the form of a two-dimensional function on the plane “delay time - Doppler frequency shift”, which displays the distribution of objects by range, radial velocity and reflection coefficient. If a linear frequency modulated (LFM) signal is used as the radiation signal, then its coordinated processing can be performed by the homodyne method, in this case, the reference signal of the quadrature mixer 6 is the emitted signal. At the same time, a beat signal is formed at its output between the signal radiated and reflected from the target. The Fourier spectrum of the beat signal unambiguously displays the distance to the object and its reflectivity.

Due to the fact that when the power P ₀ radiated into the space of the probing signal, the power at the supply input of each of the circulators 4 of the inventive device is N times less, then the penetration of the radiation signal to the input of each of the receiving channels is N times less ceteris paribus (the same elements by which the device is implemented), the maximum radiation power in the inventive device, which maintains its operability, is N times greater than in the prototype device.

This means that the energy potential of the claimed radar is N times higher than that of the prototype radar.

Claims (1)

A continuous-wave radar survey station, including a probe signal generator with a periodic phase change, a continuous oscillator, an antenna, a circulator, a low-noise amplifier, a quadrature mixer, a matched filter, while the output of the reference oscillator is connected to the input of the probe signal shaper, the circulator output connected to the input of a low-noise amplifier, the output of a low-noise amplifier is connected to the input of a quadrature mixer, characterized in that in it Two identical radio signal splitters, N-1 circulators, N-1 low-noise amplifiers, N-1 quadrature mixers, two identical N-input signal adders, were introduced separately, and the antenna is made in the form of an N-element antenna array, while the input of the first radio signal splitter is connected with the output of the probe signal generator, and its outputs are connected to the first inputs of the circulators, the input of the second splitter of radio signals is connected to the output of the reference continuous oscillator, and its outputs are connected to the first inputs of the quad mixer, and the output of each of the elements of the antenna array is connected to the second input of the corresponding circular, and the output of each of the circulators is connected to the input of the corresponding low-noise amplifier, the outputs of each of which are connected to the second input of the corresponding quadrature mixer, and the I-outputs of each of the quadrature mixers are connected with the inputs of the N-input first signal adder, and the Q-outputs of each of the quadrature mixers are connected to the inputs of the second signal adder, and the outputs of the first and second Signal adders are connected to inputs I and Q of the matched filter.