KR101273183B1 - Calibration of active multi polarimetric radar system - Google Patents

Abstract

An active multipolar polarization radar system is provided. The active multipolar radar system according to the present invention includes a circuit for oscillating and receiving multiple polarized waves and an antenna for receiving the multiple polarized waves, in order to calibrate an active multiple polarized radar system. The radar system is calibrated by forming a junction point and measuring a reflected signal generated due to a threshold mismatch at the junction point in the field with the electromagnetic anechoic chamber and using the ratio of the reflected signal. In this way, unlike conventional calibration techniques, correction constants can be derived using reflected signals reflected from the inside of the system without the installation of a reference target in the field, making it difficult to install a reference target. Calibration can also be performed at. In addition, since the reflected signal inside the radar system is used, it is easy to reduce the cost and time compared to the conventional calibration technique.

Description

Calibration method of active multipolar radar system {Calibration of active multi polarimetric radar system}

The present invention relates to a method for calibrating an active multipolar radar system, and more specifically, unlike conventional calibration techniques, a correction constant is calculated by using a reflected signal reflected back from the system without installing a reference target in the field. In addition, it is possible to derive the calibration in the observation environment where it is not easy to install the reference target, and to use the reflected signal inside the radar system, thereby reducing the cost and time compared to the existing calibration technology. The present invention relates to a calibration method for an active multipolar radar system.

The calibration technique of existing active radar systems requires simultaneous measurement of reference targets (eg corner reflectors) to measure targets in the field. That is, this measurement can be performed only after first performing a linear calibration using the reference target.

However, it is difficult to calibrate the system by conventional methods in sites where reference targets are difficult to install (eg offshore, tidal flats, polar ice).

In more detail, the outline of a basic active radar system is as follows.

First, all active radar systems have the main purpose of observing the backscattering coefficients of the target.In order to measure accurate backscattering coefficients of the targets using all the active radar systems, the main lobe of the electromagnetic beam emitted from the system antenna Direction and the bore-sight direction of the target must match exactly. Therefore, in all active radar systems, the backscattering coefficient of the target and the system noise varying depending on the observation environment are observed at the same time. Therefore, a calibration process is essential to observe the backscattering coefficient of the target accurately. With the technology to date, this calibration process is difficult to calibrate the system by the conventional method in the field where it is difficult to install the reference target.

Therefore, the present invention is designed to be able to calibrate without a reference target in the field, it is an urgent situation to invent a new calibration technology that can be applied in the field difficult to use the existing calibration technology.

Active calibration of the radar system is a technique that can be used in a wide range of fields, including not only the defense industry, that is, the defense industry, but also fisheries, for example, the detection of living things in tidal flats. The demand for technology that can eliminate and efficiently calibrate

Therefore, the object of the present invention, unlike the existing calibration calibration technology, it is possible to derive a correction constant by using the reflected signal reflected back from the inside of the system without the installation of the reference target in the field, it is not easy to install the reference target An active multipolar radar system capable of performing calibration in an observation environment is provided.

It is still another object of the present invention to provide an active multi-polarization radar system that is easy to reduce cost and time compared to conventional calibration techniques because it uses reflected signals inside the radar system.

The calibration method of an active multi-polarization radar system according to the present invention comprises a radar system having a circuit for oscillating a plurality of polarized electromagnetic waves, and constructing an antenna for receiving the electromagnetic waves, by using the radar system. Performing reference target observation for all observation directions of the radar system to be observed in the field, constructing a database, performing a radar system observation for a new reference point defined in the electromagnetic anechoic chamber, After the observation of the radar system for the reference point, the observation of the desired target, the calculation of the correction constant through the ratio of the observed value to the reference point conducted in the field with the electromagnetic anechoic chamber, and the reference target The database data and the correction constant Establishing a database for a reference target in the field using the method, and calculating system noise in a reference target database in the established field using the theoretical backscattering coefficient for the reference target, wherein the correction constant Denotes a reflection loss due to a threshold mismatch at the junction between the transmission line of the circuit of the radar system and the antenna, and the defined new reference point is the junction.

The radar system includes a vertical polarization oscillator for oscillating vertical polarization, a horizontal polarization oscillator for oscillating horizontal polarization, a vertical receiver for receiving vertical polarization received from an antenna, a horizontal receiver for receiving horizontal polarization received from an antenna, and the vertical and And a switch control line for changing a horizontal polarized wave and a transmission line of electromagnetic waves received from the antenna.

In addition, the method for calibrating an active multipolar radar system according to the present invention includes a circuit for oscillating and receiving multiple polarizations and an antenna for receiving the multiple polarizations in order to calibrate an active multipolarization radar system. The circuit and the antenna form a junction point, and the reflected signal generated due to the threshold mismatch at the junction point is measured in the field with the electromagnetic wave anechoic chamber and using the ratio of the reflected signal to calibrate the radar system.

In this way, unlike conventional calibration techniques, correction constants can be derived using reflected signals reflected from the inside of the system without the installation of a reference target in the field, making it difficult to install a reference target. Calibration can also be performed at. In addition, since the reflected signal inside the radar system is used, it is easy to reduce the cost and time compared to the conventional calibration technique.

According to the present invention, unlike a conventional calibration technique, a correction constant can be derived by using a reflected signal reflected from the inside of the system without installing a reference target in the field, thereby making it difficult to install a reference target. There is an effect that can perform the calibration.

In addition, since the reflected signal inside the radar system is used, it is easy to reduce the cost and time compared to the conventional calibration technique.

1 is a calibration circuit diagram of an active radar system according to the present invention.
2 is a flowchart of a calibration method according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. Like reference symbols in the drawings denote like elements.

1 is a calibration circuit diagram of an active radar system according to the present invention.

As shown in the drawing, in the radar system 100, electromagnetic waves of vertical polarization T _V and horizontal polarization T _H are generated in the vertical polarization oscillator 110 and the horizontal polarization oscillator 120, respectively, along the transmission line. Electromagnetic waves are transmitted. Electromagnetic waves are selectively transmitted along the corresponding line in the switch control line 130. For example, vertical polarization is transmitted along the T _V transmission line, and horizontal polarization is transmitted along the T _H transmission line.

The transmitted electromagnetic waves are affected by the noise inside the system in the transmission line and radiated through the antenna 200, and the electromagnetic waves reflected and returned from the target are transmitted along the corresponding line in the switch control line 130 via the antenna and then circulated. It is received by the vertical or horizontal receivers 170 and 180 via a circulator 150. For example, the received vertical polarization is transmitted along the R _V transmission line, and the received horizontal polarization is transmitted along the R _H transmission line. In the reception process, electromagnetic waves are affected by noise along the transmission line through which electromagnetic waves are received.

At this time, in order to be able to quantitatively calculate system noise without installing a reference target, a reflected signal is generated due to an impedance mismatch at the junction 160 of the transmission line of the system and the antenna. This is defined as return loss, and the technique calculates the ratio of the reflected signal generated at this junction in the laboratory and field of the electromagnetic anechoic chamber. That is, the junction 160 of the transmission line of the system 100 and the antenna 200 is defined as a new reference point.

That is, since the ratio calculated in the present invention also represents the degree of change in system noise generated due to the observation environment, it can be used as a correction constant in the existing calibration calibration technique. Thus, using the method according to the invention, it is possible to calibrate an active radar system like conventional calibrating techniques without a reference target.

That is, unlike conventional calibration techniques, calibration constants can be derived using the reflected signal reflected back from the system without installing a reference target in the field. Can be performed. In addition, since the reflected signal inside the radar system is used, it is easy to reduce the cost and time compared to the conventional calibration technique.

In order to explain in detail the calibration method according to the present invention, FIG. 2 is a flowchart of a calibration method according to the present invention.

As shown in the drawing, first, reference target observation is performed on all observation directions of the radar system to be observed in the field in the electromagnetic anechoic chamber, and the database is constructed (S1 and S2).

In addition, the radar system observation for a new reference point defined in the electromagnetic anechoic chamber is performed (S3). After performing the radar system observation on the new reference point in the field, the observation on the desired target is performed (S4). Here, the new reference point defined is the junction of the antenna with the transmission line of the circuit of the radar system as described above.

Next, the correction constant value is calculated through the ratio of the observed value with respect to the reference point carried out in the field and the electromagnetic anechoic chamber (S5).

Next, a database of reference targets in the field is constructed by using database data and correction constants of previously constructed reference targets (S6).

Next, using the theoretical backscattering coefficient for the reference target (S7), the system noise is calculated from the reference target database at the established site.

In this way, unlike conventional calibration techniques, correction constants can be derived using reflected signals reflected from the inside of the system without the installation of a reference target in the field, making it difficult to install a reference target. Calibration can also be performed at. In addition, since the reflected signal inside the radar system is used, it is easy to reduce the cost and time compared to the conventional calibration technique.

100: radar system 110: vertically polarized oscillator
120: horizontally polarized oscillator 130: switch control line
130: circulator 160: junction of the antenna
170: vertical receiver 180: horizontal receiver
200: antenna

Claims (3)

Configuring a radar system having a circuit for oscillating a plurality of polarized electromagnetic waves, and an antenna for receiving the electromagnetic waves;
Using the radar system, performing reference target observation on all observation directions of the radar system to be observed in the field in the electromagnetic anechoic chamber, preparing database data on a reference target observation value;
Performing a radar system observation on a new reference point defined in the electromagnetic anechoic chamber;
Performing a radar system observation on a new reference point in the field and then performing a observation on a desired target;
Calculating a correction constant based on a ratio between the electromagnetic anechoic chamber and the observed value with respect to the reference point performed in the field;
Constructing a database of reference targets in the field by using previously prepared database data of the reference target observation values and the correction constants; And
Calculating system noise in a reference target database at a built site using the theoretical backscattering coefficients for the reference target;
Including;
The correction constant defines the reflected signal due to the threshold mismatch at the junction between the transmission line of the circuit of the radar system and the antenna as the return loss, and the defined new reference point is the junction point. Calibration method of polarized radar system. The method of claim 1,
The radar system
A vertical polarization oscillator for oscillating vertical polarization;
A horizontal polarization oscillator for oscillating horizontal polarization;
A vertical receiver for receiving vertical polarization received from an antenna;
A horizontal receiver for receiving horizontal polarizations received from an antenna; And
A switch control line for changing transmission lines of the electromagnetic waves received from the vertical and horizontal polarized waves and the antenna;
Calibration method of an active multi-polarization radar system comprising a. To calibrate an active multipolar radar system,
Providing circuitry for oscillating and receiving multiple polarizations and an antenna for receiving said multiple polarizations and making junctions with said circuits;
Measuring the reflected signal generated in the electromagnetic anechoic chamber and the field respectively due to the threshold mismatch at the junction;
Calculating a ratio of the reflected signals measured in the electromagnetic anechoic chamber and the field, respectively;
Calculating a correction constant using the ratio of the reflected signals; And
Calibrating the radar system by calculating noise of the radar system using the correction constant;
Calibration method of an active multi-polarization radar system comprising a.

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