KR101647700B1 - Radar cross section profile computation method and apparatus of dummy object using radio wave augmentation device - Google Patents

Abstract

A radar cross-sectional profile calculating apparatus for a simulated object according to an embodiment of the present invention includes a radar cross-sectional profile calculating unit that is installed at a reference position of a simulated object main body, One or more radio wave amplification modules for amplifying the radar cross-sectional area size to obtain a corresponding radar cross-sectional area distribution; And a remote radio controller for controlling the one or more radio wave amplification modules to change the radar cross-sectional area size so as to derive a radar cross-sectional profile characteristic of the simulated object body using the radar cross-sectional area distribution.

Description

TECHNICAL FIELD [0001] The present invention relates to a radar cross-sectional profile calculation device and a method for calculating a radar cross-sectional profile of a simulated object using a radio wave amplification module,

Field of the Invention [0002] The present invention relates to a radar cross-sectional profile calculation technique, and more particularly, to an apparatus and a method for calculating a radar cross-sectional profile for a simulated object using a radio wave amplification module.

Particularly, in the radar test using a simulation object performed to acquire the distribution of the cross-sectional area of the object with respect to the distance of the object and to grasp characteristics of the object, a radio wave amplification module is installed near the simulation object or simulation object, And an apparatus and a method for calculating a radar cross-sectional profile for an object.

The radar has a function of detecting the size and / or position of the object by receiving the radio wave scattered from the object through the radiated radio wave. The cross-sectional area of the radar is the plane area specified to reflect the reflectance of the reflector when the radio waves transmitted from the radar are reflected back to the object.

Since the radar reflectance differs depending on the shape of the reflector, the cross-sectional area of the radar is represented by a flat metal plate area having an equivalent reflection amount. When the object is detected by the high resolution radar, the radar cross section for the distance direction can be obtained, and the radar cross section of the object is distributed in accordance with the radar resolution and the size and shape of the object.

When the radar resolution is determined, the radar cross-sectional profile according to the size and shape of the object corresponding to the radar resolution can be obtained. Finally, if the radar cross-sectional profile of a specific object is obtained from the radar, the information about the size and shape of the object can be derived based on the profile.

Therefore, if the radar cross-sectional profile and related characteristics of the size and shape of a vehicle, a vehicle, a ship, etc. corresponding to the radar object are known in advance, the radar cross-sectional profile obtained through the radar can be observed, And the radar will be able to know what kind of object has been detected. This method can be applied to a system for operating a radar because the type of the object can be inferred and determined through analysis of the radar cross-sectional profile detected by the radar.

In order to analyze the radar cross-sectional profile of a specific object, a radar test is performed using a simulated object so as to reduce cost and time. At this time, it is necessary to accurately derive the radar cross-sectional area distribution for the simulated object.

However, the radar cross-sectional area distribution may be arbitrarily varied in terms of the radar cross-sectional area with respect to time, and there may be a radar cross-sectional area due to objects other than the object of interest, such as interference echo, and the radar cross-sectional area below the noise level may not be observed. In this case, it is difficult to accurately distinguish the radar cross-sectional profile by the simulated object among the radar cross-sectional area distributions obtained from the radar. As a result, the size of the simulated object can not be accurately derived and the size and shape of the object can not be precisely deduced .

FIG. 1 shows an example of a one-dimensional radar cross-sectional area distribution with respect to a distance direction obtained through a radar. Referring to FIG. 1, radial cross-sectional area distributions of A, B, 1, 2, 3, 4, 5, and C are shown with respect to the distance direction. Radar cross-sectional area distribution 1, 2, 3, 4 and 5 are the radar cross-sectional profile by the object, the radar cross-sectional area distributions A, B and C are interference echo and the radar sectional area distribution by objects other than the object of interest, Ref. 1, Ref. 2 is noise power of a specific detection time, it becomes difficult to accurately discriminate the radar cross-sectional area distribution due to the object of interest.

Ideally, there is no A, B, or C, and Ref. 1, 2, 3, 4, and 5 exist at the noise level of 1, the distance from 1 to 5 can be determined as the one-dimensional size of the object. However, Ref. For a noise level of 2, the radar cross-sectional area 5 is not detected and the distance from 1 to 4 is misinterpreted as the size of the object.

In addition, if there are radar cross-sectional areas such as A, B, and C, the size and position of the object may be misleading, and may be misinterpreted as the cross-sectional area due to the interference echo even though it is the actual cross-sectional area.

In practice, it is a sufficiently feasible phenomenon to occur in radar testing using a simulated object, and even in the case of a radar test using a conventional simulated object, it is difficult to accurately define a radar cross sectional profile by a simulated object.

Thus, the distribution of the cross-sectional area of the radar has ambiguity. Such ambiguity makes it difficult to analyze the profile of the radar cross-section of the object and makes the radar difficult to detect the object size, shape, attitude and position.

1. Korean Laid-Open Patent No. 10-2009-0131571 2. Korean Patent No. 10-1233745

1. Kwon, Tae-joon, et al., "Estimation of Radial Cross-Sectional Area by Analysis of Shape Element", Journal of Military Science and Technology, Vol. 15, No. 4, Vol. 59 (Aug. 2012) pp.417-423.

The present invention has been devised to solve the problem according to the above background art, and it is an object of the present invention to provide a radio wave amplification module which is remotely controlled by a simulated object, And an object of the present invention is to provide a radar cross-sectional profile calculating apparatus and method for a simulated object that can accurately derive a radar cross-sectional profile for a radar cross-sectional profile.

In order to achieve the above-described object, the present invention provides a radio wave amplification module that is remotely controlled by a simulated object, and the radar cross-sectional area of the formed reference position is remotely increased or decreased to accurately determine a radar cross- A radar cross-sectional profile calculating device for obtaining a simulated object which can be obtained.

The radar cross-sectional profile calculating device comprises:

And a radar cross-sectional area distribution calculating unit that is installed at a reference position of the simulated object main body and amplifies the radar cross-sectional area size to obtain a radar cross-sectional area distribution corresponding to a physical propagation scattering point position of the simulated object body in accordance with a radar cross- The above radio wave amplification module; And

And a remote radio controller for controlling the one or more radio wave amplification modules to change the radar cross-sectional area size so as to derive a radar cross-sectional profile characteristic of the simulated object body using the radar cross-sectional area distribution. can do.

In this case, the reference position may be a specific distance value measured in advance.

Also, the radar cross-sectional area amplification section in which the cross-sectional area of the radar at a specific position in the radar cross-sectional area distribution is increased or decreased may be a reference position equipped with the one or more radio wave amplification modules.

In addition, the radar cross-sectional area size between the distances L1, which is the size of the simulated object main body, is determined as the propagation scattering point by the simulated object main body.

In addition, the characteristics of the radar cross-sectional profile may be a shape or an attitude of the simulated object main body.

The one or more radio wave amplification modules may be an electrical amplification module or a mechanical amplification module.

Here, the electrical amplification module may include: an amplification execution unit having a reception antenna for receiving a signal from the radar, an amplifier for amplifying the received signal, and a transmission antenna for transmitting the amplified signal to the radar; A control circuit for receiving a control signal from the remote radio controller and generating a control command; a switch for performing on or off of the amplification performing unit in accordance with a control command of the control circuit; and a power supply battery And a control unit having a control unit.

At this time, the mechanical amplification module includes: a passive device of a Luneburg lens or a corner reflector having a radar cross-sectional area; an amplification module having a shielding membrane for opening and closing the passive device; and a shielding membrane control circuit for controlling the shielding membrane. A control circuit for receiving a control signal from the remote radio controller to generate a control command; a switch for performing on / off of the slider control circuit part in accordance with a control command of the control circuit; and a power supply for supplying power to the switch And a control unit having a battery.

In addition, the cross-sectional area of the radar at the reference position where the radio wave amplification module is installed is increased in the on-state, and becomes relatively smaller in the off-state than in the on-state.

Another embodiment of the present invention, on the other hand, comprises the steps of remotely transmitting signals to one or more radio wave amplification modules installed at one or more reference positions of a simulated object body using a remote radio controller; Amplifying the radar cross-sectional area size of the simulated object main body to change the radar cross-sectional area size by the one or more radio wave amplification modules; Obtaining a radar cross-sectional area distribution corresponding to a physical propagation scattering point position of the simulated object body using the radar cross-sectional area size; And deriving a radar cross-sectional profile characteristic of the simulated object body using the radar cross-sectional area distribution.

According to the present invention, when the radio wave amplification module is mounted at the reference position of the simulated object, the radial cross-sectional size of the reference position at which the radio wave amplification module is installed can be remotely adjusted. Therefore, when the radar cross-sectional area distribution obtained in the radar is observed in real time, it is possible to determine that the portion where the radar cross-sectional area is changed is the propagation scattering point by the reference position on which the radio wave amplification module is mounted. By this determination, the distance information between the reference position and the specific position of the object is known in advance, which is advantageous in calculating the radar cross-sectional profile for the simulated object.

Further, as another effect of the present invention, when two or more of the radio wave amplification modules are used apart from each other, since the separation distance is known, the relative direction of the radar and the object can be known and the posture of the simulated object can be determined therefrom .

1 is an example of a radar cross-sectional area distribution graph for a general distance.
2 is a conceptual diagram for calculating a radar cross-sectional profile for a simulated object using one propagation amplifier module according to an embodiment of the present invention.
3 is a conceptual diagram for calculating a radar cross-sectional profile for a simulated object using two radio wave amplification modules according to another embodiment of the present invention.
4 is a block diagram of an electric wave amplification module according to an embodiment of the present invention.
5 is a block diagram of a mechanical wave amplification module according to another embodiment of the present invention.
6 is a flowchart illustrating a process of calculating a radar cross-sectional profile for a simulated object using a radio wave amplification module according to an embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for similar elements in describing each drawing.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The term "and / or" includes any combination of a plurality of related listed items or any of a plurality of related listed items.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Should not.

Hereinafter, a method for calculating a radar cross-sectional profile for a simulated object using a radio wave amplification module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Prior to describing the present invention, important terms are summarized as follows.

The cross-sectional area of the radar is the plane area specified to reflect the reflectance of the reflector when the radio waves transmitted from the radar are reflected back to the object.

2 is a conceptual diagram of a radar cross-sectional profile calculating apparatus 200 for a simulated object using a radio wave amplification module according to an embodiment of the present invention. 2, the simulated object test irradiates the simulated object main body 210 with the antenna beam 221 of the radar 220 to the simulated object main body 210. As shown in Fig.

A radar cross-sectional profile generated in the simulated object main body 210 is acquired and / or analyzed to allow the radar 220 to determine the size, position, and posture of the simulated object body 210. [

The radar cross-sectional profile calculation apparatus 200 according to an embodiment of the present invention calculates the cross-sectional profile of the radar cross-sectional profile by using the radio wave amplification module 230 as a reference of the simulated object body 210 And the operator of the radar 220 can remotely control the radio wave amplification module 230 through the remote radio controller 240. [

The size L1 (255) of the simulated object body 210 and the reference position P1 (253) where the wave amplification module 230 is installed are measured in advance and the radar test is started in a state in which the distance value is known.

In the radar 220, the radar cross-sectional area distribution is obtained as shown in the graph of FIG. At this time, when the radio wave controller 230 is turned on / off in real time so that the radio wave amplifier module 230 operates using the remote controller 240, as shown in the graph of FIG. 2, Which can be observed by the radar operator. The radar 220 becomes a high-resolution radar.

The radar cross sectional area amplification part 251 for increasing or decreasing the cross-sectional area of the specific position becomes the reference position P1 253 on which the radio wave amplification module 230 is mounted. The radar cross section between the distance L1 255 in the obtained radar cross-sectional area distribution is known from the simulated object main body 210 because the position of P1 253 and the size L1 255 of the simulated object main body 210 are known in advance. Can be determined as the propagation scattering point. In this way, characteristics of the radar cross-sectional profile according to the shape of the model object body 210 can be derived.

3 is a conceptual diagram for calculating a radar cross-sectional profile for a simulated object using two radio wave amplification modules according to another embodiment of the present invention. Referring to FIG. 3, the actual simulated object has a relative angle with the radar, and the radar cross-sectional profile according to the specific posture of the simulated object is analyzed. By using two or more radio wave amplification modules 330a and 330b, it is possible to more easily determine the posture of the simulated object 210 in the case of using one. In FIGS. 2 and 3, the simulation object is exemplified as a vehicle, but the present invention is not limited to this and is applicable to other moving objects.

The first radio wave amplifying device 330a is installed in P1 and the remaining radio wave amplifying module 330b is installed in P2 and the radar test is performed in a state in which the distance D1 311 between P1 and P2 is measured in advance.

In the radar 220, the radar cross-sectional area distribution is obtained as shown in the following graph. At this time, if the first and second radio wave amplification modules 130a and 130b are controlled to turn on / off in real time using the remote controller 240, The radar operator can observe that the cross-sectional area of the radar increases or decreases at the position.

It is possible to determine the distance D2 between the cross sectional area increase / decrease sections 2 and 4 where the cross sectional area of the radar at the specific position increases or decreases and the relative distance between the simulation object main body 210 and the radar 220 The angle?, That is, the posture of the simulated object main body 210 can be determined.

When two or more radio wave amplification modules are used, it may be advantageous to determine the posture of the object.

4 is a block diagram of an electric wave amplification module according to an embodiment of the present invention. Referring to FIG. 4, the electric wave amplification module 230E includes an amplification unit 430 for performing amplification and a control unit 411 for controlling the amplification unit 430. FIG. The amplification executing unit 430 includes a receiving antenna 431 for receiving a signal from the radar 220 in FIG. 2, an amplifier 432 for amplifying the received signal, and a transmitter for transmitting the amplified signal to the radar 220 And an antenna 433.

The control unit 411 for controlling the on / off operation of the amplification execution unit 430 includes a control circuit 411a for receiving a control signal from a remote radio controller (240 in FIG. 2) to generate a control command, A switch 411b for performing an on / off operation of the amplification execution unit 430 according to a control command of the switch 411b and a power supply battery 411c for supplying power to the switch 411b. The amplification execution unit 430 and the control unit 411 are connected through a power cable. Of course, wireless cable is also possible.

At this time, the cross-sectional area of the radar at the reference position where the radio wave amplification module 130E is installed increases in the 'on' state and decreases in the 'off' state.

5 is a block diagram of a mechanical wave amplification module according to another embodiment of the present invention. Referring to FIG. 5, a control unit 411 is used similarly to the electric propagation amplification module 230E shown in FIG. The mechanical wave amplification module 130M includes an amplification execution unit 530 and a control unit 411 for controlling the amplification execution unit 530.

The amplification executing unit 530 includes a passive device 534 having a large radar cross section such as a Lunberg lens or a corner reflector, a curtain 535 for opening and closing the passive device 534, A shade control circuit portion 536 for controlling opening and closing, and the like.

The amplification execution unit 530 and the control unit 411 are connected through a power cable. The radar cross section area at the reference position where the radio wave amplifying device 230M is installed is increased in the 'open' state and becomes relatively small in the 'closed' state.

6 is a flowchart illustrating a process of calculating a radar cross-sectional profile for a simulated object using a radio wave amplification module according to an embodiment of the present invention. Referring to FIG. 6, one or more radio wave amplification modules 230, 230 of FIG. 2 installed at one or more reference positions of a simulated object body 210 (FIG. 2) using a remote radio controller (240 of FIG. 2) (Steps S610 and S620).

Thereafter, the radar 220 monitors the radar cross-sectional area distribution in real time to determine whether there is a change in the radar cross-sectional area distribution (steps S630 and S640). In other words, the radio wave amplification module amplifies the cross-sectional area size of the simulated object body 210 to confirm whether the radar cross-sectional area is changed.

As a result of the determination, if there is no change in the radar cross-sectional area in step S640, steps S630 to S640 are repeated.

On the other hand, if there is a change in the radar cross-sectional area in step S640, it is determined as a propagation scattering point and a radar cross-sectional profile is calculated (step S660).

200: Radar Cross Section Profile Calculation Device
210: Simulated object body
220: Radar
230: Radio wave amplification module
230E: Electrical amplification module
230M: Mechanical amplification module
240: remote radio controller
330a, 330b: a radio wave amplification module
411:
430: amplification execution unit
431: Receive antenna 432: Amplifier
433: transmitting antenna
530:
534: Passive device
535: Shield
536: Shielding film control circuit

Claims (10)

And a radar cross-sectional area distribution calculating unit that is installed at a reference position of the simulated object main body and amplifies the radar cross-sectional area size to obtain a radar cross-sectional area distribution corresponding to a physical propagation scattering point position of the simulated object body in accordance with a radar cross- The above radio wave amplification module; And
And a remote radio controller controlling the one or more radio wave amplification modules to change the radar cross-sectional area size so as to derive a radar cross-sectional profile characteristic of the simulated object body using the radar cross-sectional area distribution,
Wherein the one or more radio frequency amplification modules are electrical amplification modules or mechanical amplification modules,
Wherein the electrical amplification module comprises: an amplification execution unit having a reception antenna for receiving a signal from the radar, an amplifier for amplifying the received signal, and a transmission antenna for transmitting the amplified signal to the radar; A control circuit for receiving a control signal from the remote radio controller and generating a control command; a switch for performing on or off of the amplifying unit according to a control command of the control circuit; and a power supply battery Wherein the radar cross-sectional area profile calculating unit calculates the cross-sectional area profile of the simulated object based on the calculated cross-sectional area profile.
The method according to claim 1,
Wherein the reference position is a specific distance value measured in advance.
The method according to claim 1,
Wherein the radar cross-sectional area amplification portion in which the cross-sectional area of the radar at a specific position in the radar cross-sectional area distribution is increased or decreased is a reference position at which the one or more radio-wave amplification modules are mounted.
The method according to claim 1,
Wherein the radar cross-sectional area size between the distances L1, which is the size of the simulated object main body, is determined as a propagation scattering point by the simulated object main body.
The method according to claim 1,
Wherein the radar cross-sectional profile characteristic is a shape or posture of the simulated object main body.
delete delete The method according to claim 1,
The mechanical amplification module comprises:
An amplification execution unit having a Lunberg lens having a radar cross section, an Lambertian lens for opening and closing the Luneburg lens, and a shading film control circuit for controlling the shading film; And
A control circuit for receiving a control signal from the remote radio controller to generate a control command; a switch for performing on / off of the shroud control circuit section in accordance with a control command of the control circuit; and a power supply battery Wherein the radar cross-sectional area profile calculating unit calculates the cross-sectional area profile of the simulated object based on the calculated cross-sectional area profile.
The method according to claim 1,
Wherein the radar cross-sectional area of the reference position at which the radio wave amplification module is installed increases in an on-state, and becomes relatively smaller in an off-state than in the on-state.
Remotely transmitting a signal to one or more radio wave amplification modules installed at one or more reference positions of a simulated object body using a remote radio controller;
Amplifying the radar cross-sectional area size of the simulated object main body to change the radar cross-sectional area size by the one or more radio wave amplification modules;
Acquiring a radar cross-sectional area distribution corresponding to a physical propagation scattering point position of the simulated object body using a radar cross-sectional area size of the high-resolution radar; And
Wherein the radar uses the radar cross-sectional area distribution to derive a radar cross-sectional profile characteristic of the simulated object body,
Wherein the one or more radio frequency amplification modules are electrical amplification modules or mechanical amplification modules,
Wherein the electrical amplification module comprises: an amplification execution unit having a reception antenna for receiving a signal from the radar, an amplifier for amplifying the received signal, and a transmission antenna for transmitting the amplified signal to the radar; A control circuit for receiving a control signal from the remote radio controller and generating a control command; a switch for performing on or off of the amplifying unit according to a control command of the control circuit; and a power supply battery A radar cross-sectional area profile calculating step of calculating a radar cross-sectional area profile of the simulation object based on the calculated cross-sectional area profile;

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