KR102512910B1 - Synthetic aperture radar system and method of generating synthetic aperture image using first unmanned air vehicle and second unmanned air vehicle - Google Patents

Abstract

A SAR system and method for generating SAR images using a first unmanned aerial vehicle and a second unmanned aerial vehicle may be disclosed. A SAR system according to an embodiment includes a first SAR radar module that transmits a radar signal, receives a first reflected signal reflected from a target, etc., and generates a first received signal by performing signal processing on the first reflected signal. a first unmanned aerial vehicle; a second unmanned aerial vehicle including a second SAR radar module that transmits a radar signal, receives a second reflected signal reflected from a target, etc., and generates a second received signal by performing signal processing on the second reflected signal; and controlling chirp rates and positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle, performing subaperture synthesis processing on each of the first received signal and the second received signal, and subaperture synthesis. A signal processing server generating a SAR image by synthesizing the processed first received signal and the second received signal may be included.

Description

SAR system and method for generating SAR images using a first unmanned aerial vehicle and a second unmanned aerial vehicle

The present invention relates to a SAR system and method for generating SAR images using a first unmanned aerial vehicle and a second unmanned aerial vehicle.

The SAR (synthetic aperture radar) system coherently synthesizes radar signals received from multiple locations so that the phases match, so that the size of the antenna aperture is kept small while improving the azimuth resolution. It is a system. Due to the advantage of being able to collect high-resolution image information in all weathers day and night, it is mounted on manned/unmanned aircraft or artificial satellites to provide important data for land, marine, and polar exploration or, in particular, for military use.

Conventionally, a SAR signal (eg, a video SAR signal) is generated using one unmanned aerial vehicle (eg, a drone) and N ² logN fastback projection. In this way, since one unmanned aerial vehicle is used in the prior art, high-performance hardware is required, and the signal reception time required to generate the first SAR image takes time plus synthetic aperture time (SAT) and computation time. . In addition, since a video SAR signal requires a large amount of computation, it is difficult to construct a video SAR system using a small unmanned aerial vehicle (eg, a drone).

The present invention can provide a SAR system and a method for generating a SAR image capable of reducing the time required to generate a synthetic aperture radar (SAR) image using a first unmanned aerial vehicle and a second unmanned aerial vehicle.

According to one embodiment of the present invention, a synthetic aperture radar (SAR) system may be disclosed. A SAR system according to an embodiment includes a first SAR radar module for generating a first received signal by transmitting a radar signal, receiving a first reflected signal reflected from a target, etc., and performing signal processing on the first reflected signal. A first unmanned aerial vehicle comprising; A second unmanned aerial vehicle including a second SAR radar module configured to transmit the radar signal, receive a second reflected signal reflected from the target, and generate a second received signal by performing the signal processing on the second reflected signal aircraft; and controlling chirp rates and positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle, and performing subaperture synthesis processing on each of the first received signal and the second received signal, and a signal processing server generating a SAR image by synthesizing the first received signal and the second received signal subjected to the subaperture synthesizing process.

In one embodiment, the chirp rates may have different signs of slopes between the first SAR radar module and the second SAR module.

In one embodiment, each of the first SAR radar module and the second SAR radar module sets the chirp rate based on the control signal, and generates a chirp signal for obtaining the SAR image based on the chirp rate a waveform generator to generate; a transmitter connected to the waveform generator and generating the radar signal based on the chirp signal; a SAR antenna connected to the transmitting unit and transmitting the radar signal to receive a reflected signal; a receiving unit connected to the SAR antenna and generating a received signal based on the reflected signal; a signal processor connected to the receiver, performing analog-to-digital conversion on the received signal, and performing preprocessing on the digitally converted received signal to generate a preprocessed signal; a data link communication unit connected to the signal processing server, transmitting the preprocessed signal to the signal processing server, and receiving the control signal from the signal processing server; and a controller configured to set the chirp rate and the position based on the control signal.

In one embodiment, the control unit may equally set the center frequency of the radar signal for each of the first SAR radar module and the second SAR radar module based on the control signal.

In one embodiment, the signal processing unit may perform polar grid subaperture backprojection processing to reduce the data amount of the digitally converted received signal as the preprocessing.

In one embodiment, the signal processing server receives the first received signal subjected to polar grid subaperture back-projection processing from the first unmanned aerial vehicle and transmits the control signal to the first unmanned aerial vehicle. data link communication unit; a second data link communication unit for receiving the second received signal subjected to the polar grid subaperture back-projection process from the second unmanned aerial vehicle and transmitting the control signal to the second unmanned aerial vehicle; a first subaperture synthesizing unit connected to the first data link communication unit and generating a first synthesized signal by performing the subaperture synthesizing process on the first received signal subjected to the polar grid subaperture back-projection process; a second subaperture synthesizing unit connected to the second data link communication unit and generating a second synthesized signal by performing the subaperture synthesizing process on the second received signal subjected to the polar grid subaperture back-projection process; a synthesized aperture radar signal synthesizer generating the SAR image based on the first synthesized signal and the second synthesized signal; And it may include a server control unit for generating the control signal.

In an embodiment, the first subaperture synthesizer may generate the first synthesized signal by interpolating and adding the polar grid subaperture back-projected first received signal to a rectangular coordinate system image.

In an embodiment, the second subaperture synthesizer may generate the second synthesized signal by interpolating and adding the second received signal subjected to the polar grid subaperture back-projection process to a rectangular coordinate system image.

In one embodiment, the synthesized aperture radar signal synthesizer may generate the SAR image by correcting the first synthesized signal and the second synthesized signal and synthesizing the corrected first synthesized signal and the second synthesized signal. there is.

In one embodiment, the synthesized aperture radar signal synthesizer determines a phase error between the first synthesized signal and the second synthesized signal using a cost function, and obtains the SAR image based on the phase error. can create

In one embodiment, the server control unit adjusts the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle such that a distance between the first unmanned aerial vehicle and the second unmanned aerial vehicle is “Synthetic Aperture Length (SAL) / 2”. The control signal to be set can be generated.

In one embodiment, the server control unit in the case of a circular SAR (circular SAR)

(Equation 1)

Based on Equation 1, the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle is generated, and in Equation 1, c represents the speed of light, and fc represents the center frequency. , R denote distances between the first and second unmanned aerial vehicles and the center of the SAR image, and ρ _a may denote a target resolution.

In one embodiment, the server control unit in the case of a stripmap SAR

(Equation 2)

The control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle is generated based on Equation 2, wherein c represents the speed of light, and fc represents the center frequency. , R denote distances between the first and second unmanned aerial vehicles and the center of the SAR image, and ρ _a may denote a target resolution.

According to an embodiment of the present invention, a method for generating a SAR image in a SAR system may be disclosed. The SAR image generating method according to an embodiment includes generating control signals for controlling chirp rates and positions of the first and second unmanned aerial vehicles of the SAR system in a signal processing server of the SAR system; In the first unmanned aerial vehicle, a radar signal is transmitted based on the control signal through a first SAR radar module, a first reflection signal reflected from a target is received, and signal processing is performed on the first reflection signal to obtain a first reflection signal. 1 generating a received signal; In the second unmanned aerial vehicle, the radar signal is transmitted based on the control signal through a second SAR radar module and a second reflection signal reflected from the target is received, and the second reflection signal is subjected to the signal processing. Generating a second received signal by performing; performing, in the signal processing server, subaperture synthesizing processing on each of the first received signal and the second received signal; and synthesizing, in the signal processing server, the first received signal and the second received signal subjected to the subaperture synthesizing process to generate a SAR image.

In one embodiment, the chirp rates may have different signs of slopes between the first SAR radar module and the second SAR module.

In one embodiment, the generating of the first received signal may include setting the chirp rate based on the control signal in a waveform generator of the first SAR radar module; generating, in the waveform generator, a first chirp signal for acquiring the SAR image based on the chirp rate; generating a first radar signal based on the first chirp signal in a transmitter of the first SAR radar module; Transmitting the first radar signal and receiving a first reflection signal from the SAR antenna of the first SAR radar module; generating the first received signal based on the first reflected signal in a receiver of the first SAR radar module; performing analog-to-digital conversion on the first received signal in a signal processing unit of the first SAR radar module; and generating a first pre-processed signal by performing pre-processing on the digitally-converted first received signal in the signal processing unit.

In one embodiment, the step of performing preprocessing on the digitally converted first received signal to generate the first preprocessed signal reduces the amount of data of the digitally converted first received signal with a polar grid subaperture back It may include performing projection processing.

In one embodiment, generating the first radar signal based on the first chirp signal may further include setting a center frequency of the first radar signal equal to that of the second SAR radar module. .

In one embodiment, the generating of the second received signal may include setting the chirp rate based on the control signal in a waveform generator of the second SAR radar module; generating a second chirp signal for obtaining the SAR image based on the chirp rate in the waveform generator; generating a second radar signal based on the second chirp signal in a transmitter of the second SAR radar module; transmitting the second radar signal and receiving a second reflection signal from the SAR antenna of the second SAR radar module; generating the second received signal based on the second reflected signal in the receiver of the second SAR radar module; performing analog-to-digital conversion on the second received signal in a signal processing unit of the second SAR radar module; and generating a second pre-processed signal by performing pre-processing on the digitally converted second received signal in the signal processing unit.

In one embodiment, the step of performing preprocessing on the digitally converted second received signal to generate the second preprocessed signal reduces the amount of data of the digitally converted second received signal with a polar grid subaperture back It may include performing projection processing.

In one embodiment, generating the second radar signal based on the second chirp signal may further include setting a center frequency of the second radar signal equal to that of the first SAR radar module. .

In an embodiment, the step of performing subaperture synthesizing processing on each of the first received signal and the second received signal comprises subaperture synthesizing on the first received signal subjected to polar grid subaperture back-projection processing. performing processing to generate a first composite signal; and generating a second synthesized signal by performing the subaperture synthesis process on the second received signal subjected to the polar grid subaperture back-projection process.

In one embodiment, the generating of the first synthesized signal includes generating the first synthesized signal by interpolating and adding the polar grid subaperture back-projected first received signal to a Cartesian coordinate system image. can do.

In one embodiment, the generating of the second synthesized signal includes generating the second synthesized signal by interpolating and adding the second received signal subjected to the polar grid subaperture back-projection process to a Cartesian coordinate system image. can do.

In an embodiment, generating the SAR image may include correcting the first synthesized signal and the second synthesized signal; and generating the SAR image by synthesizing the corrected first synthesized signal and the second synthesized signal.

In an embodiment, the generating of the SAR image may include determining a phase error between the first synthesized signal and the second synthesized signal using a cost function; and generating the SAR image based on the phase error.

In one embodiment, the generating of the control signal may include the first unmanned aerial vehicle and the second unmanned aerial vehicle such that a distance between the first unmanned aerial vehicle and the second unmanned aerial vehicle is “Synthetic Aperture Length (SAL) / 2”. It may include generating the control signal for setting the position of the vehicle.

In one embodiment, generating the control signal comprises

(Equation 3)

In the case of circular SAR, generating the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle based on Equation 3, wherein c is the speed of light , fc denotes a center frequency, R denotes a distance between the first and second unmanned aerial vehicles and the center of the SAR image, and ρ _a denotes a target resolution.

In one embodiment, generating the control signal comprises

(Equation 4)

In the case of strip map SAR, generating the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle based on Equation 4, wherein c is light Denotes velocity, fc denotes a center frequency, R denotes a distance between the first and second unmanned aerial vehicles and the center of the SAR image, and ρ _a denotes a target resolution.

According to various embodiments of the present invention, the first unmanned aerial vehicle and the second unmanned aerial vehicle can be spaced apart by “Synthetic Aperture Length (SAL) / 2” and moved along the same path, which takes the signal collection time to generate the first SAR image. The synthetic aperture time (SAT) can be reduced by half.

In addition, a chirp rate having the same absolute value of the slope and a different sign of the slope may be used for the first and second UAVs, thereby minimizing RF interference between the first UAV and the second UAV. there is.

In addition, since the same center frequency may be used for the first and second unmanned aerial vehicles, azimuth resolution may be increased by synthesizing signals obtained from the first and second unmanned aerial vehicles.

In addition, since preprocessing can be performed in each of the first and second unmanned aerial vehicles, hardware specifications for preprocessing can be lowered, and polar grid subaperture back projection is performed in each of the first and second unmanned aerial vehicles. Since grid subaperture backprojection can be performed, the required data rate of the data link can be lowered.

In addition, it is possible to synthesize preprocessed signals from each of the first and second unmanned aerial vehicles using a signal processing method through the synthesized aperture radar signal synthesis unit, so that fine details between the radar of the first unmanned aerial vehicle and the radar of the second unmanned aerial vehicle can be synthesized. A series of procedures for correcting hardware errors can be omitted.

Moreover, according to various embodiments of the present invention, it can be used to build a surveillance system using an unmanned aerial vehicle in day and night and bad weather conditions.

1 is a schematic block diagram of a SAR system according to an embodiment of the present invention.
2 is a block diagram schematically showing the configuration of a SAR radar module according to an embodiment of the present invention.
3 is a block diagram schematically showing the configuration of a signal processing server according to an embodiment of the present invention.
4 is a diagram showing distances between a first unmanned aerial vehicle and a second unmanned aerial vehicle in the case of a circular SAR according to an embodiment of the present invention.
5 is a diagram showing distances between a first unmanned aerial vehicle and a second unmanned aerial vehicle in the case of a stripmap SAR according to an embodiment of the present invention.
6 is a flowchart illustrating a method of generating a SAR image according to an embodiment of the present invention.

Embodiments of the present invention are illustrated for the purpose of explaining the technical idea of the present invention. The scope of rights according to the present invention is not limited to the specific description of the embodiments or these embodiments presented below.

All technical terms and scientific terms used in the present invention have meanings commonly understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined. All terms used in the present invention are selected for the purpose of more clearly describing the present invention and are not selected to limit the scope of rights according to the present invention.

Expressions such as "comprising", "including", "having", etc. used in the present invention are open-ended terms that imply the possibility of including other embodiments, unless otherwise stated in the phrase or sentence in which the expression is included. (open-ended terms).

Singular expressions described in the present invention may include plural meanings unless otherwise stated, and this applies to singular expressions described in the claims as well.

Expressions such as "first" and "second" used in the present invention are used to distinguish a plurality of components from each other, and do not limit the order or importance of the components.

The term "unit" used in the present invention means software or a hardware component such as a field-programmable gate array (FPGA) or an application specific integrated circuit (ASIC). However, "unit" is not limited to hardware and software. A “unit” may be configured to reside in an addressable storage medium and may be configured to reproduce on one or more processors. Thus, as an example, "unit" refers to components such as software components, object-oriented software components, class components and task components, processes, functions, properties, procedures, subroutines, It includes segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays and variables. Functions provided within components and “units” may be combined into fewer components and “units” or separated into additional components and “units”.

As used herein, the expression "based on" is used to describe one or more factors that affect the action or operation of a decision judgment, described in a phrase or sentence in which the expression is included, and this expression refers to a decision However, it does not preclude additional factors that affect the act or operation of the judgment.

In the present invention, when an element is referred to as being “connected” or “connected” to another element, that element is directly connectable or connectable to the other element, or a new or different configuration. It should be understood that it can be connected or connected via an element.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the accompanying drawings, identical or corresponding elements are given the same reference numerals. In addition, in the description of the following embodiments, overlapping descriptions of the same or corresponding components may be omitted. However, omission of a description of a component does not intend that such a component is not included in an embodiment.

1 is a schematic block diagram of a SAR system according to an embodiment of the present invention. Referring to FIG. 1 , the SAR system 100 may include a first unmanned aerial vehicle 110, a second unmanned aerial vehicle 120, and a signal processing server 130.

The first unmanned aerial vehicle 110 may transmit a radar signal and receive a reflected signal reflected from a target (hereinafter, referred to as a "first reflected signal"). In addition, the first unmanned aerial vehicle 110 may generate a received signal (hereinafter referred to as “first received signal”) based on the first reflected signal. The first unmanned aerial vehicle 110 may include a first SAR radar module 111 .

In one embodiment, the first SAR radar module 111 may set a first chirp rate. For example, the first SAR radar module 111 may set first chirp rates having different inclination signs for the second unmanned aerial vehicle 120 .

The second unmanned aerial vehicle 120 may transmit a radar signal and receive a reflected signal (hereinafter referred to as a “second reflected signal”) reflected from a target, etc. In addition, the second unmanned aerial vehicle 120 may receive a second reflected signal. A received signal (hereinafter referred to as “second received signal”) may be generated based on the signal The second unmanned aerial vehicle 120 may include a second SAR radar module 121.

In one embodiment, the second SAR radar module 121 may set the second chirp rate. For example, the second SAR radar module 121 may set a second chirp rate having a different sign of the slope from the first chirp rate.

The signal processing server 130 may be connected to the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . The signal processing server 130 may control chirp rates and positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . In addition, the signal processing server 130 performs a subaperture synthesizing process on each of the first received signal and the second received signal, and the first received signal and the second received signal subjected to the subaperture synthesized process. SAR images can be generated by synthesis.

2 is a block diagram schematically showing the configuration of a SAR radar module according to an embodiment of the present invention. Referring to FIG. 2, the SAR radar module 111 or 112 includes a waveform generator 210, a transmitter 220, a SAR antenna 230, a receiver 240, a signal processor 250, and a data link communication unit 260. And it may include a control unit 270.

The waveform generator 210 may generate a chirp signal for obtaining a SAR image. In one embodiment, the waveform generator 210 may generate a chirp signal based on a chirp rate.

For example, the waveform generator 210 of the first SAR radar module 111 may generate a chirp signal (hereinafter, referred to as a “first chirp signal”) based on the first chirp rate. In addition, the waveform generator 210 of the second SAR radar module 121 may generate a chirp signal (hereinafter referred to as “second chirp signal”) based on the second chirp rate.

The transmitter 220 may be connected to the waveform generator 210 . The transmitter 220 may generate a radar signal based on the chirp signal. In one embodiment, the transmitter 220 may receive a chirp signal from the waveform generator 210 and generate a radar signal based on the received chirp signal.

For example, the transmitter 220 of the first SAR radar module 111 receives the first chirp signal and generates a radar signal (hereinafter referred to as “first radar signal”) based on the received first chirp signal. can create The transmitter 220 of the second SAR radar module 121 may receive the second chirp signal and generate a radar signal (hereinafter referred to as “second radar signal”) based on the received second chirp signal. .

The SAR antenna 230 may be connected to the transmitter 220 . The SAR antenna 230 may transmit a radar signal and receive a reflected signal. In one embodiment, the SAR antenna 230 may receive a radar signal from the transmitter 220 and transmit the received radar signal. Also, the SAR antenna 230 may receive a reflected signal reflected from a target or the like.

For example, the SAR antenna 230 of the first SAR radar module 111 receives a first radar signal from the transmitter 220, transmits the received first radar signal, and reflects a reflected signal from a target, etc. ( Hereinafter referred to as "first reflection signal") may be received. In addition, the SAR antenna 230 of the second SAR radar module 121 receives the second radar signal from the transmitter 220, transmits the received second radar signal, and reflects the reflected signal from the target (hereinafter, Referred to as "second reflection signal") may be received.

The receiver 240 may be connected to the SAR antenna 230. The receiver 240 may generate a received signal based on the reflected signal. In one embodiment, the receiver 240 may receive a reflected signal from the SAR antenna 230 and generate a received signal based on the received reflected signal.

For example, the receiving unit 240 of the first SAR radar module 111 receives the first reflected signal from the SAR antenna 230, and receives a received signal (hereinafter, “first received signal”) based on the received first reflected signal. signal") can be generated. In addition, the receiving unit 240 of the second SAR radar module 121 receives the second reflected signal from the SAR antenna 230, and receives a received signal (hereinafter referred to as “second received signal”) based on the received second reflected signal. ) can be created.

The signal processing unit 250 may be connected to the receiving unit 240 . The signal processing unit 250 may perform signal processing on the received signal. In one embodiment, the signal processor 250 may receive a received signal from the receiver 240 and perform analog-to-digital conversion on the received signal. Also, the signal processing unit 250 may perform pre-processing on the analog-to-digital converted received signal.

In one embodiment, the signal processor 250 may perform polar grid subaperture backprojection processing on the analog-to-digital converted received signal. For example, polar grid subaperture backprojection can reduce the amount of data in the received signal. In an embodiment, the signal processing unit 250 may perform polar grid subaperture back-projection processing using Equation 1 below.

In Equation 1, i denotes an unmanned aerial vehicle identifier, n denotes a subaperture index, s _n denotes a pulse index at the center of the subaperture, and p denotes a position of an image pixel , q represents the position of the aircraft, and l represents the image length for subaperture back projection.

For example, the signal processing unit 250 of the first SAR radar module 111 receives the first received signal from the receiving unit 240, performs analog-to-digital conversion on the received first received signal, and converts the analog-to-digital conversion into analog and digital signals. A preprocessed signal (hereinafter, referred to as “first preprocessed signal”) may be generated by performing polar grid subaperture back-projection processing on the first received signal. In addition, the signal processor 250 of the second SAR radar module 121 receives the second received signal from the receiver 240, performs analog-to-digital conversion on the received second received signal, and converts the analog-to-digital converted second A preprocessed signal (hereinafter, referred to as a “second preprocessed signal”) may be generated by performing polar grid subaperture back-projection processing on the received signal.

The data link communication unit 260 may be connected to the signal processing server 130 . The data link communication unit 260 may transmit the signal pre-processed by the signal processing unit 250 to the signal processing server 130 . Also, the data link communication unit 260 may receive a control signal for controlling the unmanned aerial vehicle from the signal processing server 130 . In one embodiment, the control signal may include a control signal for controlling the chirp rate and the position of the unmanned aerial vehicle.

For example, the data link communication unit 260 of the first SAR radar module 111 receives a control signal from the signal processing server 130 and transmits the first preprocessing signal generated by the signal processing unit 250 to the signal processing server. (130). In addition, the data link communication unit 260 of the second SAR radar module 121 receives a control signal from the signal processing server 130 and transmits the second preprocessing signal generated by the signal processing unit 250 to the signal processing server 130. ) can be transmitted.

3 is a block diagram schematically showing the configuration of a signal processing server according to an embodiment of the present invention. Referring to FIG. 3 , the signal processing server 130 includes a first data link communication unit 311, a second data link communication unit 312, a first subaperture synthesizing unit 321, and a second subaperture synthesizing unit ( 322), a synthesized aperture radar signal synthesizer 330, and a server controller 340.

The first data link communication unit 311 may be connected to the first unmanned aerial vehicle 110 . The first data link communication unit 311 may receive the first preprocessing signal from the data link communication unit 260 of the first unmanned aerial vehicle 110 . Also, the first data link communication unit 311 may transmit a control signal for controlling the first unmanned aerial vehicle 110 to the data link communication unit 260 of the first unmanned aerial vehicle 110 . In one embodiment, the control signal may include a control signal for controlling the chirp rate and position of the first unmanned aerial vehicle 110 .

The second data link communication unit 312 may be connected to the second unmanned aerial vehicle 120 . The second data link communication unit 312 may receive the second preprocessing signal from the data link communication unit 260 of the second unmanned aerial vehicle 120 . Also, the second data link communication unit 312 may transmit a control signal for controlling the second unmanned aerial vehicle 120 to the data link communication unit 260 of the second unmanned aerial vehicle 120 . In one embodiment, the control signal may include a control signal for controlling the chirp rate and position of the second unmanned aerial vehicle 120 .

The first subaperture synthesis unit 321 may be connected to the first data link communication unit 311 . The first subaperture synthesis unit 321 may receive the first preprocessing signal from the first data link communication unit 311 and perform subaperture synthesis processing on the received first preprocessing signal. In an embodiment, the first subaperture synthesis unit 321 may generate a synthesis signal (hereinafter, referred to as a “first synthesis signal”) by interpolating and adding the first preprocessing signal to a rectangular coordinate system image. For example, the first subaperture synthesis unit 321 may generate a first synthesis signal using Equation 2 below.

In Equation 2, IR represents a first synthesized signal, i represents an unmanned aerial vehicle identifier, n represents a subaperture index, p represents a position of an image pixel, and InterpRect represents a first preprocessing signal (i.e., A polar grid image) is interpolated into a Cartesian coordinate system image.

The second subaperture synthesis unit 322 may be connected to the second data link communication unit 312 . The second subaperture synthesis unit 322 may receive the first preprocessing signal from the second data link communication unit 312 and perform subaperture synthesis processing on the received second preprocessing signal. In an embodiment, the second subaperture synthesis unit 322 may generate a synthesis signal (hereinafter, referred to as a “second synthesis signal”) by interpolating and adding the second preprocessing signal to the rectangular coordinate system image. For example, the first subaperture synthesis unit 321 may generate a second synthesis signal using Equation 2.

The synthesized aperture radar signal synthesizer 330 may be connected to the first subaperture synthesizer 321 and the second subaperture synthesizer 322 . The synthesized aperture radar signal synthesizer 330 receives a first synthesized signal from the first subaperture synthesizer 321 and receives a second synthesized signal from the second subaperture synthesizer 322. A SAR image may be generated based on the synthesized signal and the second synthesized signal.

In one embodiment, the synthesized aperture radar signal synthesizer 330 corrects the first synthesized signal and the second synthesized signal by performing signal processing, and synthesizes the corrected first synthesized signal and the second synthesized signal to obtain a SAR image. can create For example, the synthesized aperture radar signal synthesizer 330 determines a phase error between the first synthesized signal and the second synthesized signal using Equation 3 below, that is, a cost function, and determines the phase error according to the determined phase error. Based on this, a SAR image (Isar) may be generated.

The server controller 340 may control the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . In addition, the server controller 340 includes the first data link communication unit 311, the second data link communication unit 312, the first subaperture synthesizer 321, the second subaperture synthesizer 322, and the synthesized aperture. The radar signal synthesis unit 330 may be controlled.

In one embodiment, the server control unit 340 may generate a control signal for controlling the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . For example, the server control unit 340 controls the center frequency for signal synthesis between the first SAR radar module 111 of the first unmanned aerial vehicle 110 and the second SAR radar module 121 of the second unmanned aerial vehicle 120. and a control signal for setting the chirp rate.

In one embodiment, the center frequency (Fc) for the first SAR radar module 111 is the same frequency as the center frequency (Fc) for the second SAR radar module 121, and the first SAR radar module 111 The chirp rate for the second SAR radar module 121 and the sign of the slope may be different from each other in order to minimize RF interference.

Accordingly, the waveform generator 210 of the first SAR radar module 111 of the first unmanned aerial vehicle 110 may set the first chirp rate based on the control signal provided from the signal processing server 130 . In addition, the transmitter 220 of the first SAR radar module 111 of the first unmanned aerial vehicle 110 may set the center frequency Fc based on the control signal provided from the signal processing server 130. Therefore, the transmission frequency (F 1 (t)) of the radar signal output from the transmitter 220 of the first SAR radar module 111 of the first unmanned aerial vehicle 110 is " _{F 1 (} t) = F _c + Bw /T _p * t". Here, Bw represents a bandwidth (bandwidth [Hz]), Tp represents a pulse width (Pulsewidth [sec]), and t represents time ([sec]). Furthermore, the waveform generator 210 of the second SAR radar module 12 of the second unmanned aerial vehicle 120 may set the second chirp rate based on a control signal provided from the signal processing server 130 . In addition, the transmitter 220 of the second SAR radar module 121 of the second unmanned aerial vehicle 120 may set the center frequency Fc based on the control signal provided from the signal processing server 130. Therefore, the transmission frequency (F 1 (t)) of the radar signal output from the transmitter 220 of the second SAR radar module 121 of the second unmanned aerial vehicle 120 is " _{F 2 (} t) = F _c - Bw /T _p * t".

In one embodiment, the server control unit 340 may generate a control signal for setting the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . For example, a control signal for setting a separation distance between the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 may be generated.

In one embodiment, in the case of circular SAR, the server control unit 340 may set the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 as shown in FIG. 4 . 4, θ and dc may be defined as in Equation 4 below.

In Equation 4, c represents the speed of light, fc represents the center frequency ([Hz]), R represents the distance between the unmanned aerial vehicle and the center of the image, and ρ _a represents the target resolution ([m]) .

In one embodiment, in the case of a stripmap SAR, the server control unit 340 may set the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 as shown in FIG. 5 . In FIG. 5 , θ and ds may be defined as in Equation 5 below.

Although process steps, method steps, algorithms, etc. are described in sequential order in the flowcharts shown herein, such processes, methods and algorithms may be configured to operate in any suitable order. In other words, the steps of the processes, methods and algorithms described in the various embodiments of the invention need not be performed in the order described herein. Also, although some steps are described as being performed asynchronously, in other embodiments some of these steps may be performed concurrently. Further, illustration of a process by depiction in the drawings does not mean that the illustrated process is exclusive of other changes and modifications thereto, and that any of the illustrated process or steps thereof may be one of various embodiments of the present invention. It is not meant to be essential to one or more, and it does not imply that the illustrated process is preferred.

6 is a flowchart illustrating a method of generating a SAR image according to an embodiment of the present invention. Referring to FIG. 6 , in step S602, the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 may set a center frequency and a chirp rate. In one embodiment, the server control unit 340 of the signal processing server 130 includes the first SAR radar module 111 of the first unmanned aerial vehicle 110 and the second SAR radar module of the second unmanned aerial vehicle 120 ( 121) may generate a control signal for setting a center frequency and a chirp rate for signal synthesis between the signals. The first SAR radar module 111 of the first unmanned aerial vehicle 110 may set a center frequency and a chirp rate based on a control signal. In addition, the second SAR radar module 121 of the second unmanned aerial vehicle 120 may set the center frequency and chirp rate based on the control signal.

In step S604, the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 may be set. In one embodiment, the server control unit 340 of the signal processing server 130 may generate a control signal for setting the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 . For example, the server control unit 340 controls the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 so that the interval between the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 is “Synthetic Aperture Length (SAL) / 2”. A control signal for setting the position of the unmanned aerial vehicle 120 may be generated. Accordingly, the positions of the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 may be set based on the control signal.

In step S606, the first unmanned aerial vehicle 110 and the second unmanned aerial vehicle 120 may perform a video SAR mission. In one embodiment, the first SAR radar module 111 of the first unmanned aerial vehicle 110 transmits a radar signal to receive a first reflected signal, generates a first received signal based on the first reflected signal, , A first preprocessing signal may be generated by performing polar grid subaperture back-projection on the first received signal. In addition, the second SAR radar module 121 of the second unmanned aerial vehicle 120 transmits a radar signal to receive a second reflection signal, generates a second reception signal based on the second reflection signal, and generates a second reception signal. A second preprocessing signal may be generated by performing polar grid subaperture back-projection on the signal.

In step S608, the signal processing server 130 may perform subaperture synthesis processing on the first pre-processed signal provided from the first unmanned aerial vehicle 110 and the second pre-processed signal provided from the second unmanned aerial vehicle 120. there is. In one embodiment, the signal processing server 130 may generate a first synthesized signal by interpolating and adding the first preprocessing signal provided from the first unmanned aerial vehicle 110 to the Cartesian coordinate system image. In addition, the signal processing server 130 may generate a second synthesized signal by interpolating and adding the second preprocessed signal provided from the second unmanned aerial vehicle 120 to the rectangular coordinate system image.

In step S610, the signal processing server 130 may generate a SAR image based on the first synthesized signal and the second synthesized signal. In one embodiment, the signal processing server 130 performs signal processing on the first synthesized signal and the second synthesized signal to correct them, and synthesizes the corrected first synthesized signal and the second synthesized signal to generate a SAR image. there is.

Although the above method has been described through specific embodiments, it is also possible to implement the above method as computer readable code on a computer readable recording medium. A computer-readable recording medium includes all types of recording devices storing data that can be read by a computer system. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices. In addition, the computer-readable recording medium is distributed in computer systems connected through a network, so that computer-readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the above embodiments can be easily inferred by programmers in the technical field to which the present invention belongs.

Although the technical idea of the present invention has been described by the examples shown in some embodiments and the accompanying drawings, it does not deviate from the technical spirit and scope of the present invention that can be understood by those skilled in the art to which the present invention belongs. It will be appreciated that various substitutions, modifications and alterations may be made within the range. Moreover, such substitutions, modifications and alterations are intended to fall within the scope of the appended claims.

100: SAR system, 110: first unmanned aerial vehicle, 111: first SAR radar module, 120: second unmanned aerial vehicle, 121: second SAR radar module, 130: signal processing server, 210: waveform generator, 220: transmission unit , 230: SAR antenna, 240: receiver, 250: signal processor, 260: data link communication unit, 270: control unit, 311: first data link communication unit, 312: second data link communication unit, 321: first sub-aperture synthesis unit , 322: second subaperture synthesis unit, 330: synthesis aperture radar signal synthesis unit, 340: server control unit

Claims (29)

As a synthetic aperture radar (SAR) system,
A first unmanned aerial vehicle including a first SAR radar module that transmits a radar signal, receives a first reflected signal reflected from a target, etc., and generates a first received signal by performing signal processing on the first reflected signal;
A second unmanned aerial vehicle including a second SAR radar module configured to transmit the radar signal, receive a second reflected signal reflected from the target, and generate a second received signal by performing the signal processing on the second reflected signal aircraft; and
Controls chirp rates and positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle, performs subaperture synthesis processing on each of the first received signal and the second received signal, A signal processing server generating a SAR image by synthesizing the first received signal and the second received signal subjected to sub-aperture synthesis processing
A SAR system comprising a. The SAR system according to claim 1, wherein the chirp rates have different signs of slopes between the first SAR radar module and the second SAR module. The method of claim 1, wherein each of the first SAR radar module and the second SAR radar module
a waveform generator configured to set the chirp rate based on a control signal generated by a signal processing server and to generate a chirp signal for acquiring the SAR image based on the chirp rate;
a transmitter connected to the waveform generator and generating the radar signal based on the chirp signal;
a SAR antenna connected to the transmitting unit and transmitting the radar signal to receive a reflected signal;
a receiving unit connected to the SAR antenna and generating a received signal based on the reflected signal;
a signal processor connected to the receiver, performing analog-to-digital conversion on the received signal, and performing preprocessing on the digitally converted received signal to generate a preprocessed signal;
a data link communication unit connected to the signal processing server, transmitting the preprocessed signal to the signal processing server, and receiving the control signal from the signal processing server; and
A controller configured to set the chirp rate and the position based on the control signal
A SAR system comprising a. 4. The SAR system of claim 3, wherein the controller sets the same center frequency of the radar signal for each of the first SAR radar module and the second SAR radar module based on the control signal. 4. The SAR system of claim 3, wherein the signal processing unit performs polar grid subaperture backprojection processing to reduce the data amount of the digitally converted received signal as the preprocessing. The method of claim 5, wherein the signal processing server
a first data link communication unit for receiving the first received signal subjected to the polar grid subaperture back-projection process from the first unmanned aerial vehicle and transmitting the control signal to the first unmanned aerial vehicle;
a second data link communication unit for receiving the second received signal subjected to the polar grid subaperture back-projection process from the second unmanned aerial vehicle and transmitting the control signal to the second unmanned aerial vehicle;
a first subaperture synthesizing unit connected to the first data link communication unit and generating a first synthesized signal by performing the subaperture synthesizing process on the first received signal subjected to the polar grid subaperture back-projection process;
a second subaperture synthesizing unit connected to the second data link communication unit and generating a second synthesized signal by performing the subaperture synthesizing process on the second received signal subjected to the polar grid subaperture back-projection process;
a synthesized aperture radar signal synthesizer generating the SAR image based on the first synthesized signal and the second synthesized signal; and
Server control unit generating the control signal
A SAR system comprising a. 7. The SAR system of claim 6, wherein the first subaperture synthesis unit generates the first synthesis signal by interpolating and adding the polar grid subaperture back-projected first received signal to a Cartesian coordinate system image. 7. The SAR system of claim 6, wherein the second subaperture synthesis unit generates the second synthesis signal by interpolating and adding the second received signal subjected to the polar grid subaperture back-projection process to a Cartesian coordinate system image. The SAR of claim 6 , wherein the synthesized aperture radar signal synthesizer corrects the first synthesized signal and the second synthesized signal and synthesizes the corrected first synthesized signal and the second synthesized signal to generate the SAR image. system. The method of claim 6, wherein the synthesis aperture radar signal synthesis unit
determining a phase error between the first composite signal and the second composite signal using a cost function;
The SAR system for generating the SAR image based on the phase error. The method of claim 6, wherein the server control unit determines the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle so that a distance between the first unmanned aerial vehicle and the second unmanned aerial vehicle is “Synthetic Aperture Length (SAL) / 2”. The SAR system for generating the control signal to set. The method of claim 11, wherein the server controller is circular SAR (circular SAR)
(Equation 1)

generating the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle based on Equation 1;
In Equation 1, c represents the speed of light, fc represents the center frequency, R represents the distance between the first UAV and the second UAV and the center of the SAR image, and ρ _a is the target resolution A SAR system representing . The method of claim 11, wherein the server control unit in the case of a stripmap SAR
(Equation 2)

generating the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle based on Equation 2;
In Equation 2, c represents the speed of light, fc represents the center frequency, R represents the distance between the first UAV and the second UAV and the center of the SAR image, and ρ _a is the target resolution A SAR system representing . As a method for generating a SAR image in a SAR system,
generating, at the signal processing server of the SAR system, control signals for controlling chirp rates and positions of the first and second unmanned aerial vehicles of the SAR system;
In the first unmanned aerial vehicle, a radar signal is transmitted based on the control signal through a first SAR radar module, a first reflection signal reflected from a target is received, and signal processing is performed on the first reflection signal to obtain a first reflection signal. 1 generating a received signal;
In the second unmanned aerial vehicle, the radar signal is transmitted based on the control signal through a second SAR radar module and a second reflection signal reflected from the target is received, and the second reflection signal is subjected to the signal processing. Generating a second received signal by performing;
performing, in the signal processing server, subaperture synthesizing processing on each of the first received signal and the second received signal; and
Generating, in the signal processing server, a SAR image by synthesizing the first received signal and the second received signal subjected to the sub-aperture synthesizing process.
SAR image generation method comprising a. 15. The method of claim 14, wherein the chirp rates have different signs of slopes between the first SAR radar module and the second SAR module. 15. The method of claim 14, wherein generating the first received signal
setting the chirp rate based on the control signal in the waveform generator of the first SAR radar module;
generating, in the waveform generator, a first chirp signal for acquiring the SAR image based on the chirp rate;
generating a first radar signal based on the first chirp signal in a transmitter of the first SAR radar module;
Transmitting the first radar signal and receiving a first reflection signal from the SAR antenna of the first SAR radar module;
generating the first received signal based on the first reflected signal in a receiver of the first SAR radar module;
performing analog-to-digital conversion on the first received signal in a signal processing unit of the first SAR radar module; and
Generating, in the signal processing unit, a first preprocessed signal by performing preprocessing on the digitally converted first received signal.
SAR image generation method comprising a. The method of claim 16, wherein generating a first preprocessed signal by performing preprocessing on the digitally converted first received signal
performing polar grid subaperture back-projection processing to reduce the data amount of the digitally converted first received signal;
SAR image generation method comprising a. 17. The method of claim 16, wherein generating a first radar signal based on the first chirp signal
Setting the center frequency of the first radar signal to be the same as that of the second SAR radar module
SAR image generation method further comprising a. 18. The method of claim 17, wherein generating the second received signal
setting the chirp rate based on the control signal in the waveform generator of the second SAR radar module;
generating a second chirp signal for obtaining the SAR image based on the chirp rate in the waveform generator;
generating a second radar signal based on the second chirp signal in a transmitter of the second SAR radar module;
transmitting the second radar signal and receiving a second reflection signal from the SAR antenna of the second SAR radar module;
generating the second received signal based on the second reflected signal in the receiver of the second SAR radar module;
performing analog-to-digital conversion on the second received signal in a signal processing unit of the second SAR radar module; and
Generating, in the signal processing unit, a second preprocessed signal by performing preprocessing on the digitally converted second received signal.
SAR image generation method comprising a. The method of claim 19, wherein generating a second preprocessed signal by performing preprocessing on the digitally converted second received signal
performing polar grid subaperture back-projection processing to reduce the data amount of the digitally converted second received signal;
SAR image generation method comprising a. The method of claim 19, wherein generating a second radar signal based on the second chirp signal
Setting the center frequency of the second radar signal to be the same as that of the first SAR radar module.
SAR image generation method further comprising a. 21. The method of claim 20, wherein performing subaperture synthesis processing on each of the first received signal and the second received signal comprises:
generating a first composite signal by performing the subaperture synthesis process on the first received signal subjected to the polar grid subaperture back-projection process; and
Generating a second composite signal by performing the subaperture synthesis process on the second received signal subjected to the polar grid subaperture back-projection process
SAR image generation method comprising a. 23. The method of claim 22, wherein generating the first composite signal
Generating the first synthesized signal by interpolating and adding the polar grid subaperture back-projection-processed first received signal to a Cartesian coordinate system image
SAR image generation method comprising a. 23. The method of claim 22, wherein generating the second composite signal
Generating the second synthesized signal by interpolating and adding the second received signal subjected to the polar grid subaperture back-projection process to a Cartesian coordinate system image
SAR image generation method comprising a. 23. The method of claim 22, wherein generating the SAR image
correcting the first composite signal and the second composite signal; and
Generating the SAR image by synthesizing the corrected first synthesized signal and the second synthesized signal
SAR image generation method comprising a. 23. The method of claim 22, wherein generating the SAR image
determining a phase error between the first composite signal and the second composite signal using a cost function; and
Generating the SAR image based on the phase error
SAR image generation method comprising a. 15. The method of claim 14, wherein generating the control signal
Generating the control signal for setting positions of the first and second unmanned aerial vehicles such that a distance between the first and second unmanned aerial vehicles is “Synthetic Aperture Length (SAL) / 2”
SAR image generation method comprising a. 28. The method of claim 27, wherein generating the control signal
(Equation 3)

Generating the control signal for setting the positions of the first unmanned aerial vehicle and the second unmanned aerial vehicle based on Equation 3 in the case of circular SAR
including,
In Equation 3, c represents the speed of light, fc represents the center frequency, R represents the distance between the first UAV and the second UAV and the center of the SAR image, and ρ _a is the target resolution SAR image generation method representing . 28. The method of claim 27, wherein generating the control signal
(Equation 4)

In the case of a strip map SAR, generating the control signal for setting the positions of the first and second unmanned aerial vehicles based on Equation 4 above.
including,
In Equation 4, c represents the speed of light, fc represents the center frequency, R represents the distance between the first UAV and the second UAV and the center of the SAR image, and ρ _a is the target resolution SAR image generation method representing .

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