KR102551830B1 - Azimuth simulated signal generator, method and computer program of operation thereof - Google Patents

Abstract

An apparatus for generating a simulated bearing signal according to an embodiment of the present invention includes a signal generator for generating a simulated source signal in a predetermined frequency range and inputting the simulated source signal to a simulated signal generator; And the orientation simulator for controlling at least one of the frequency, intensity, and phase of the source simulation signal to generate a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for testing, wherein the orientation simulator includes the orientation simulation signal. The simulator performs an azimuth detection or signal detection function using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal.

Description

Azimuth simulation signal generator, its operation method and computer program {AZIMUTH SIMULATED SIGNAL GENERATOR, METHOD AND COMPUTER PROGRAM OF OPERATION THEREOF}

The present invention relates to an apparatus for generating a simulated bearing signal and a method for operating the same, and more particularly, to an apparatus and method for generating a simulated azimuth signal for each multi-channel.

Direction finding (DF) technology is a technology that finds the direction of a radar that tracks a target using electromagnetic waves, a guided weapon, or a communication device using electromagnetic waves. The core of electronic warfare support (ES) equipment is do. Direction information obtained through this is used as preprocessing data of a signal processor to improve the efficiency of signal analysis, or is used in electronic attack (EA) equipment to enable effective jamming.

Recently, the form of smart warfare is changing to a smart war that selectively attacks only targets based on advanced digital weapons, refraining from wars in the form of indiscriminate mass destruction and destruction of the past, along with more accurate and rapid direction detection. A lot of research is being done on the technology.

Direction detection methods include a rotation direction detection method, an amplitude comparison method, a phase comparison method, and an amplitude-phase composite comparison method. Among them, the phase comparison method is the most commonly used method to accurately determine the position of an emitter in a wide frequency domain.

In addition, according to the phase comparison method, reception of an arbitrary signal is based on a calibration table including an angle of arrival (AOA) of an angular interval corresponding to the resolution of direction finding and phase difference data corresponding thereto. The azimuth of arrival of the signal is estimated.

For direction finding device development and performance test using the phase comparison method, it is necessary to simulate the phase of each channel mapped to the arrival azimuth of the signal to be detected at the multi-antenna receiving signal input terminal of the direction finding device. In order to check direction finding performance under various conditions, it is necessary to check the result of estimating the azimuth of arrival of the direction finding device according to the change in the frequency, azimuth, and modulation method of the signal to be performed for direction finding. To this end, a multi-channel azimuth simulation signal generator capable of generating by changing the phase of a test signal output through multiple channels according to changes in the frequency and azimuth of the modulated signal for the test is required.

Embodiments of the present invention are a device capable of simulating the arrival azimuth of a test signal for measuring the accuracy of a direction finding device by generating an azimuth simulation signal for each multi-channel having a necessary frequency and phase based on a fixed frequency signal and a frequency hopping signal. and to provide a method thereof.

An apparatus for generating a simulated bearing signal according to an embodiment of the present invention includes a signal generator for generating a simulated source signal in a predetermined frequency range and inputting the simulated source signal to a simulated signal generator; And the orientation simulator for controlling at least one of the frequency, intensity, and phase of the source simulation signal to generate a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for testing, wherein the orientation simulator includes the orientation simulation signal. The simulator performs an azimuth detection or signal detection function using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal.

The operation mode of the orientation simulator includes a first orientation simulation mode using one fixed frequency signal; a second azimuth simulation mode using two fixed frequency signals; a third azimuth simulation mode using the frequency hopping simulation signal; a fourth azimuth simulation mode using two fixed frequency signals generated from two independent sources having the same fixed frequency; and a signal detection mode for simultaneously outputting the frequency hopping simulated signal, the narrowband signal, and the wideband signal using at least two or more fixed frequency signals.

The azimuth simulator includes an input selection plate for performing internal frequency up/down conversion on the simulated signal received from the signal generator and generating an IF signal including the frequency hopping simulated signal hopping in a wide band; a phase conversion plate that receives the IF signal generated from the input selection plate, performs frequency up/down conversion, and outputs a multi-channel azimuth simulation signal in the RF band by controlling the phase and intensity for each channel; and a simultaneous signal generating board for simultaneously outputting multi-channel azimuth simulation signals independently phase-controlled and wideband simulation signals through switch control based on the multi-channel azimuth simulation signals received from the phase conversion plate. there is.

The azimuth simulation signal generating device is used to perform self-correction of the azimuth simulation signal generating device, and a network for checking the phase, phase control range, phase control error, and phase control deviation of input/output channels of the azimuth simulation signal generating device. An analyzer; may further include.

The azimuth simulation signal generator may further include a local signal generator for generating a reference signal required for an input selection plate and a phase conversion plate included in the orientation simulator, and outputting the variable frequency and signal strength of the reference signal. can

The orientation simulator receives a reference signal from the local signal generator, diverges the signal, supplies it to the input selection plate and the phase conversion plate, and uses the reference signal and an output signal generated from an internal OCXO, a PLO signal. a local generation distribution plate for generating a reference signal and a clock signal and transmitting them to the input selection plate and the phase conversion plate; And a correction path selection plate for self-correction, which is generated by the network analyzer and transfers the correction signal for each path generated through the RF path of the input selection plate and the phase conversion plate back to the network analyzer through switch control. can include

A method for generating a simulated bearing signal according to an embodiment of the present invention includes generating a simulated source signal in a predetermined frequency range for generating a simulated signal using a signal generator and inputting the simulated source signal to the simulated bearing device; And generating a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for a test by controlling at least one of frequency, intensity, and phase of the source simulation signal using the orientation simulator. , In the step of generating the target simulation signal, azimuth detection or azimuth detection using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal. It performs signal detection function.

The operation mode of the orientation simulator includes a first orientation simulation mode using one fixed frequency signal; a second azimuth simulation mode using two fixed frequency signals; a third azimuth simulation mode using the frequency hopping simulation signal; a fourth azimuth simulation mode using two fixed frequency signals generated from two independent sources having the same fixed frequency; and a signal detection mode for simultaneously outputting the frequency hopping simulated signal, the narrowband signal, and the wideband signal using at least two or more fixed frequency signals.

In the step of generating the target simulated signal, the simulated signal received from the signal generator is subjected to internal frequency up/down conversion using an input selection plate, and the IF signal including the frequency hopping simulated signal hops in a wide band. generating; receiving the IF signal generated from the input selection plate using a phase conversion plate, performing frequency up/down conversion, and outputting a multi-channel azimuth simulation signal of an RF band by controlling the phase and intensity for each channel; and simultaneously outputting multi-channel azimuth simulation signals independently phase-controlled and wideband simulation signals through switch control based on the multi-channel azimuth simulation signals received from the phase conversion plate using a simultaneous signal generation board; can include

In the step of generating the target simulated signal, self-calibration of the simulated orientation signal generator is performed using a network analyzer, and the phase, phase control range, phase control error, and phase control of the input/output channels of the simulated orientation signal generator are controlled. It may further include; confirming the deviation.

In the generating of the target simulation signal, a reference signal required for an input selection plate and a phase conversion plate included in the orientation simulator is generated using a local signal generator, and the frequency and signal strength of the reference signal are varied and output. Step; may further include.

In the step of generating the target simulated signal, a reference signal is received from the local signal generator using a locally generated distribution plate, the signal is branched and supplied to the input selection plate and the phase conversion plate, and the reference signal is supplied to the internal generating a reference signal and a clock signal by using an output signal and a PLO signal generated from the OCXO and transmitting them to the input selection plate and the phase conversion plate; And for self-calibration using a correction path selection plate, the correction signal for each path generated by the network analyzer through the RF path of the input selection plate and the phase conversion plate is transmitted back to the network analyzer through switch control. Step; may further include.

A computer program according to an embodiment of the present invention may be stored in a computer-readable storage medium in order to execute the above-described method of the present invention using a computer.

According to embodiments of the present invention, it is possible to simulate the arrival azimuth of a test signal for measuring the accuracy of a direction finding device by generating an azimuth simulation signal for each multi-channel having a required frequency and phase based on a fixed frequency signal and a frequency hopping signal. It is possible to provide an apparatus and method capable of

1 is a diagram for explaining the configuration of an apparatus for generating a simulated orientation signal according to an embodiment of the present invention.
2 is a diagram showing a real shape of an azimuth simulation signal generator according to an embodiment of the present invention.
3 is a flowchart illustrating a method for generating a simulated orientation signal according to an embodiment of the present invention.
4A and 4B are views for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to an embodiment of the present invention.
5A and 5B are views for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to another embodiment of the present invention.
6A and 6B are diagrams for explaining a control sequence of an azimuth simulation mode based on a frequency hopping signal according to an embodiment of the present invention.
7A and 7B are views for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to another embodiment of the present invention.
8A and 8B are diagrams for explaining a control sequence of a signal detection mode based on a frequency hopping signal according to another embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. Effects and features of the present invention, and methods for achieving them will become clear with reference to the embodiments described later in detail together with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when describing with reference to the drawings, the same or corresponding components are assigned the same reference numerals, and overlapping descriptions thereof will be omitted. .

In the following embodiments, terms such as first and second are used for the purpose of distinguishing one component from another component without limiting meaning. In the following examples, expressions in the singular number include plural expressions unless the context clearly dictates otherwise. In the following embodiments, terms such as include or have mean that features or components described in the specification exist, and do not preclude the possibility that one or more other features or components may be added. In the drawings, the size of components may be exaggerated or reduced for convenience of explanation. For example, since the size and shape of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to those shown.

In the following embodiments, when a part such as a region, component, unit, block, module, etc. is on or on another part, it is not only directly on top of the other part, but also another region, component, part in the middle thereof. , blocks, modules, etc. are also included.

In the following embodiments, when it is assumed that areas, components, parts, blocks, modules, etc. are connected, not only areas, components, parts, blocks, and modules are directly connected, but also areas, components, parts, blocks, and modules. It also includes cases in which other areas, components, parts, blocks, and modules are interposed and indirectly connected in the middle. For example, when regions, components, parts, blocks, modules, etc. are electrically connected in this specification, not only when regions, components, parts, blocks, modules, etc. are directly electrically connected, but also other regions in the middle, It also includes cases where components, parts, blocks, modules, etc. are interposed and indirectly electrically connected.

Hereinafter, the configuration and operation of the orientation simulation signal generator 10 according to an embodiment of the present invention will be described using FIGS. 1 and 2 together. 1 is a view for explaining the configuration of an orientation simulation signal generating device 10 according to an embodiment of the present invention, and FIG. 2 shows a real shape of the orientation simulation signal generating device according to an embodiment of the present invention. it is a drawing

First, the function of the azimuth simulation signal generator 10 according to the present invention will be described.

The azimuth simulation signal generator 10 measures the direction finding accuracy of a direction finding device (not shown) by simulating the direction of arrival of the narrowband/wideband signal and the azimuth of the frequency hopping signal, and analyzes and displays the result. can do.

For self-calibration of the device 10, the azimuth simulation signal generating device 10 may perform self-calibration of signal strength and phase for signal paths of multiple channels. It performs analysis of the phase characteristic data between channels of the direction finding device collected from the direction finding device, instantaneous I/Q (In-phase/Quadrature) and instantaneous phase collection data, post-processing the collected data, and performing the direction finding algorithm. analysis can be performed. In addition, the azimuth simulation signal generator 10 can perform reception channel correction performed in a laboratory and antenna characteristic correction performed in a flight simulation test facility in conjunction with a direction finding device. During radiation correction, the function of receiving the phase difference measurement result from the direction finding device, analyzing the correction data, and loading it into the direction finding device may be performed.

The azimuth simulation signal generating apparatus 10 may generate multiple simulation signals that do not simulate a bearing by controlling simulation signal generation having a plurality of independent frequencies. It is possible to simulate multiple narrowband signals, wideband signals, and frequency hopping signals required for the test according to the operator's control command of frequency, signal strength, and modulation method input through the control computer. In addition, by injecting a frequency hopping signal that simulates the direction of signal arrival into the direction finding device, it has the function of searching for the frequency hopping signal and testing the direction of the frequency hopping signal.

Hereinafter, components of the azimuth simulation signal generator 10 and its functions will be described.

The orientation simulation signal generator 10 according to the present invention may include a signal generator 100, an orientation simulator 200, a network analyzer 110, and a local signal generator 120. According to embodiments, the orientation simulation signal generator 10 may further include a cable assembly 130, an instrument assembly 140, a control computer 150, and a power/network distributor 160.

The signal generator 100 may generate a simulated signal in a predetermined frequency range to generate a simulated signal for measuring detection accuracy of the direction finding device, and input the simulated signal to the orientation simulator 200 .

The network analyzer 110 is used to self-calibrate the azimuth simulation signal generator 10, and checks the phase, phase control range, phase control error and phase control deviation of the input/output channels of the azimuth simulation signal generator 10. can

The local signal generator 120 generates a reference signal required for the input selection plate 210 and the phase conversion plate 220 included in the orientation simulator 200, and outputs the reference signal by varying the frequency and signal strength. can The reference signal may be, for example, a local oscillator 1 (LO1) signal.

The orientation simulator 200 uses the input selection plate 210 and the phase conversion plate 220, which operate as reference signals of the local signal generator 120 based on the operation command of the control computer 150, to generate a signal ( The source simulation signal received from 100) may be converted into a target simulation signal to be simulated and then output.

The orientation simulator 200 may perform self-calibration of the orientation simulation signal upon initial startup after power is applied in order to accurately simulate signal strength and phase. The self-correction of the orientation simulator 200 is generated from the network analyzer 110 and the correction signal for each path generated through the RF path of the input selection plate 210 and the phase conversion plate 220, the correction path selection plate ( It can be performed through an operation of inputting again to the network analyzer 110 through the control of the switch in step 250.

The azimuth simulator 200 controls at least one of the frequency, intensity, and phase of the source simulation signal received from the signal generator 100, so that the 'target simulation signal including an azimuth simulation signal and a frequency hopping simulation signal for testing. ' can be created. At this time, the azimuth simulator 200 performs an azimuth detection or signal detection function by using any one of the target simulation signals of the phase-controlled azimuth simulation signal, the phase-controlled frequency hopping simulation signal, and the phase-uncontrolled frequency hopping simulation signal. can be performed. The detection function of the orientation simulator 200 may include an orientation simulation mode and a signal detection mode in which orientation is not simulated.

For example, the operation mode of the orientation simulator 200 includes modes described later, and the orientation simulator 200 may operate in any one of the modes described below. The operation modes of the orientation simulator 200 include a first orientation simulation mode (S1) using one fixed frequency signal, a second orientation simulation mode (S2) using two fixed frequency signals, and a frequency hopping simulation signal using the A third azimuth simulation mode (S3), a fourth azimuth simulation mode (S4) using two fixed frequency signals generated from two independent sources having the same fixed frequency, and the frequency using at least two fixed frequency signals A signal detection mode (S5) for simultaneously outputting a simulated hopping signal, a narrowband signal, and a wideband signal may be included.

Various operation modes related to the direction detection or signal detection function of the orientation simulator 200 described above will be described in detail with reference to FIGS. 4 to 8 to be described later. A 'target simulation signal' may be a concept including an azimuth simulation signal or a signal detection signal output through an output port in a mode according to each embodiment.

Hereinafter, the detailed configuration of the orientation simulator 200 will be described. The orientation simulator 200 may include an input selection plate 210, a phase conversion plate 220, a simultaneous signal generation plate 230, a local generation distribution plate 240, and a correction path selection plate 250. The orientation simulator 200 may further include a control panel 260, a power supply plate 270, and a parent plate 280.

The input selection plate 210 performs frequency up/down conversion on the simulated signal received from the signal generator 100 using an internal DDS (Direct Digital Synthesizer) module, and includes the frequency hopping simulated signal hopping in a wide band. It is possible to generate an intermediate frequency (IF) signal that

The phase conversion plate 220 receives the IF signal generated from the input selection plate 210, performs frequency up/down conversion, and controls the phase and intensity for each channel to output a multi-channel azimuth simulation signal in the RF band. there is. The phase conversion plate 220 may include a plurality of phase conversion plates 220-1, ..., 220-n outputting multi-channel azimuth simulation signals. More specifically, the phase conversion plate 220 performs frequency up-down conversion on the IF signal received from the input selection plate 210 using an internal DDS module, and generates a multi-channel RF output signal for generating an azimuth simulation signal. Phase control can be performed and output signal strength can be adjusted using a DCA (Digital Control Attenuator) module.

Based on the multi-channel azimuth simulation signal received from the phase shifter 220, the simultaneous signal generation board 230 simultaneously outputs a multi-channel azimuth simulation signal independently phase-controlled and a broadband simulation signal through switch control. can At this time, the wideband simulated signal may include wideband signals of several bands generated by switch-controlling the wideband signal generated from the wideband signal output port of the phase shifter 220 . The multi-channel azimuth simulation signal by the simultaneous signal generator 230 may include a plurality of narrowband signals generated by switch-controlling the RF signals generated from the RF signal output ports of the phase conversion plate 220. .

The local generation distribution plate 240 may receive a reference signal from the local signal generator 120, branch the signal, and supply the signal to the input selection plate 210 and the phase conversion plate 220. In addition, a reference signal and a clock signal may be generated using an output signal generated from the internal OCXO and a PLO signal together with the reference signal, and may be transmitted to the input selection plate 210 and the phase conversion plate 220. Specifically, the local generating distribution plate 240 receives the reference signal from the local signal generator 120, branches the signal, supplies the LO1 signal to the input selection plate 210 and the phase conversion plate 220, and the local signal generator ( 120), LO2 (Local Oscillator 2) signal and DDS clock signal are generated using the output signal generated from the OCXO (Oven Controlled Crystal Oscillator) and the PLO (Phase-Locked Oscillator) signal along with the reference signal input from the input selection board. (210) and the phase change plate (220).

The correction path selection plate 250 is generated in the network analyzer for self-calibration and returns the correction signal for each path generated through the RF path of the input selection plate and the phase conversion plate to the network analyzer 110 through switch control. can be conveyed

The cable assemblies 130 are cables for inputting and outputting radio frequency (RF) signals of the orientation simulation signal generator 10 . As shown in FIG. 2 , the instrument assembly 140 may be a console type instrument manufactured to mount components of the generating device 10 and to easily store/move. The control computer 150 is loaded with software of the generating device 10 to provide an operator interface, etc., and the power/network distributor 160 supplies power supplied from the outside to each component of the generating device 10. It distributes and transmits, and can play a role in distributing Ethernet signals so that each component of the control computer 150 and the generating device 10 can be transmitted and received to transmit and receive network signals.

The control panel 260 may serve to connect the input selection plate 210 and the phase conversion plate 220 inside the orientation simulator 200 to the control computer. The power supply plate 270 receives, for example, 220V, 60Hz, AC power from the power/network distributor 160 and is required for the components of the orientation simulator 200, for example, +3.3V, +5V, ±12V DC. power can be output. The parent plate 280 may serve to provide power, data signals, and RF signal paths between components of the orientation simulator 200 .

3 is a flowchart for explaining a method for generating an azimuth simulation signal according to an embodiment of the present invention.

First, frequency control may be performed using the DDS module of the orientation simulator 200 (S100). Thereafter, phase control may be performed using the DDS module (S200). Thereafter, the RF path of the simulated signal may be controlled by controlling the switch (SW) (S300). Thereafter, it is possible to control the direction simulation signal and the broadband simulation signal to be output at the same time (S400).

According to an embodiment, the method according to the present invention may further include implementing a mute time between hopping signals for generating a frequency hopping simulation signal (S500) and adjusting the strength of an output signal (S600). .

The steps S100 to S600 according to different embodiments of the present invention will be described in more detail through the drawings to be described later.

Hereinafter, a direction simulation signal generation method according to different embodiments of the present invention will be described using FIGS. 4A to 8B. Hereinafter, a drawing with B attached after a drawing number shows a flow chart of a control sequence according to an embodiment of a drawing with A attached after the same drawing number, and will be described with reference to the drawings with the same drawing number.

Hereinafter, as an embodiment in which the azimuth simulation signal generator 10 includes five phase conversion plates 220, including two output ports for each phase conversion plate 220, including a total of 10 output ports Explain with an example. However, only one output port of the total output ports is a wideband signal output port and is connected to a signal detection device, not a direction finding device, so that a total of nine output ports for azimuth simulation signals may be provided. In addition, each phase conversion plate 220 may include two RF signal output ports, respectively. The wideband signal by the above-described wideband signal output port and the RF signals by the RF signal output ports are input to the simultaneous signal generator 230, and the wideband signal can be output as a wideband signal of several bands, and the RF signals are constant. They may be grouped according to a criterion and output as a plurality of narrowband signals.

4A and 4B (hereinafter collectively referred to as 'FIG. 4') are diagrams for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to an embodiment of the present invention. The azimuth simulation mode of this drawing is referred to as a 'first azimuth simulation mode (S1)', and the first azimuth simulation mode (S1) is an azimuth simulation for one fixed frequency signal. The orientation simulation signal generator 10 may operate in the DDS and switch control scenario shown in FIG. 4 in the first orientation simulation mode (S1).

Referring to FIG. 4, a signal flow F1 for one fixed frequency signal generated from one signal generator (eg, 100b) is shown by a thick dotted line. The separately shown signal generators 100a and 100b may generate modulated signals having independent frequencies and/or phases. For example, the signal generator 100a may generate an AM signal and the signal generator 100b may generate an FM signal.

The input selection plate 210 may convert the simulated source signal received from the signal generator 100 into a target frequency signal to be simulated through DDS1 control (frequency control) (S100). Since the step of frequency control (S100) of the embodiment (S1) of this drawing uses one fixed frequency signal, only control by either one of DDS1 and DDS2 can be performed.

Thereafter, the phase conversion plate 220 may convert the converted signal to have a target phase value for azimuth simulation through control (phase control) of DDS3 and DDS4 (S200). Thereafter, as a switch control operation, the input selection plate 210 can select an RF path for azimuth simulation based on a single frequency signal through SW3, SW4, and SW5 controls, and the phase conversion plate 220 through SW6 and SW7 controls. (S300). Thereafter, as a switch control, the phase conversion plate 220 can be controlled so that the multi-channel azimuth simulation signal and the broadband simulation signal are simultaneously output to the azimuth simulation signal output port through SW10 and SW11 control (S400).

In the present disclosure, as an example having five phase shift plates 220, since two simulated signals are output through two switches SW10 and SW11 for each phase shift plate 220, an example in which 10 output signals are output shown Referring to the 10 output ports connected to SW10 and SW11 in FIG. 4 , it can be seen that 9 channels of orientation simulation signals (CH1 to CH9) of the direction finding function and 1 channel of wideband signals are output.

5A and 5B (hereinafter collectively referred to as 'FIG. 5') are diagrams for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to another embodiment of the present invention. The azimuth simulation mode of this drawing is referred to as a 'second azimuth simulation mode (S2)', and the second azimuth simulation mode (S2) is an azimuth simulation for two fixed frequency signals. The orientation simulation signal generator 10 may operate in the DDS and switch control scenario shown in FIG. 5 in the second orientation simulation mode (S2).

Referring to FIG. 5, two signal flows F1 and F2 for two fixed frequency signals generated from one signal generator 100b are shown by thick dotted lines.

The input selection plate 210 converts the source simulation signal received from the signal generator 100 into a first target frequency (frequency-1) signal to be simulated through DDS1 control (frequency control), and DDS2 control (frequency control). ) It can be converted into a second target frequency (frequency -2) signal through (S100). In the step of frequency control (S100) of the embodiment (S2) of this drawing, since two fixed frequency signals are used, both DDS1 control and DDS2 control are performed.

Thereafter, the phase conversion plate 220 converts the first target frequency signal under the DDS1 control to have a first target phase value for azimuth simulation through the control (phase control) of DDS3 and DDS4, and similarly, the first target frequency signal under the DDS2 control The 2 target frequency signals may be converted to have a second target phase value for azimuth simulation through control (phase control) of DDS5 and DDS6 (S200).

Thereafter, as a switch control operation, the input selection plate 210 controls SW3, SW4, and SW5, and the phase conversion plate 220 controls SW6, SW7, SW8, and SW9 for azimuth simulation based on two fixed frequency signals. An RF path can be selected (S300). Thereafter, as a switch control, the phase conversion plate 220 can be controlled so that the multi-channel azimuth simulation signal and the broadband simulation signal are simultaneously output to the azimuth simulation signal output port through SW10 and SW11 control (S400).

At this time, each of the two azimuth simulation signals reflecting the target frequency and target phase values to be simulated may be combined at the ends E1 and E2 of the phase conversion plate 220 and transmitted to the azimuth simulation signal output port. Referring to the ends E1 and E2, it can be seen that two azimuth simulation signal components having different target frequencies and target phase values are summed and output at each of the ends E1 and E2. Referring to the 10 output ports connected to SW10 and SW11 in this figure as well, it can be seen that 9 channels of orientation simulation signals (CH1 to CH9) of the direction finding function and 1 channel of broadband signals are output.

6A and 6B (hereinafter collectively referred to as 'FIG. 6') are diagrams for explaining a control sequence of an azimuth simulation mode based on a frequency hopping signal according to an embodiment of the present invention. The azimuth simulation mode of this drawing is referred to as a 'third azimuth simulation mode (S3)', and the third azimuth simulation mode (S3) is an azimuth simulation for two frequency hopping signals. The orientation simulation signal generator 10 may operate in the DDS control, switch control, and DCA control scenarios shown in FIG. 6 in the third orientation simulation mode (S3).

Referring to FIG. 6, two signal flows F1 and F2 for two frequency hopping signals generated from one signal generator 100b are shown by thick dotted lines.

The input selection plate 210 converts the simulated source signal received from the signal generator 100 into a first center frequency signal to be simulated through DDS1 control (frequency control) (frequency 1 control_hopping), and DDS2 control ( frequency control) to convert to the second center frequency signal (frequency 2 control_hopping) (S100). In the step of frequency control (S100) of the embodiment (S3) of this drawing, since two frequency hopping signals are used, both DDS1 control and DDS2 control are performed. However, DDS1 and DDS2 may be controlled so that the frequencies can be independently changed based on each center frequency in order to simulate two frequency hopping signals.

Thereafter, the phase conversion plate 220 converts the first frequency hopping signal subjected to the DDS1 control to have a first target phase value for azimuth simulation through the control of DDS3 and DDS4 (frequency 1 phase control), and similarly, the DDS2 control The received second frequency hopping signal may be converted to have a second target phase value for azimuth simulation through control of DDS5 and DDS6 (frequency 2 phase control) (S200).

Thereafter, as a switch control operation, the input selection plate 210 controls SW3, SW4, and SW5, and the phase conversion plate 220 controls SW6, SW7, SW8, and SW9 for azimuth simulation based on two frequency jump signals. An RF path can be selected (S300). At this time, during step S300, the input selection plate 210 may implement a mute time between hopping signals through control of SW4 and SW5 as switch control to generate a frequency hopping signal (S500).

On the other hand, the phase conversion plate 220 can adjust the intensity of the output signal through the DCA control using the DCA module (DCA1 to DCA10) during the step S300 (S600).

The detailed sequence of steps S300, S500 and S600 is shown in the flowchart shown on the right side of this figure.

Thereafter, simultaneous output (S400) of multi-channel azimuth simulation signals and broadband simulation signals through SW10 and SW11 control is the same as described above.

As in the above-described embodiment of FIG. 5, each of the two azimuth simulation signals to which the target frequency and target phase values are reflected can be combined at the ends E1 and E2 of the phase conversion plate 220 and transmitted to the azimuth simulation signal output port. .

7A and 7B (hereinafter collectively referred to as 'FIG. 7') are diagrams for explaining a control sequence of an azimuth simulation mode based on a fixed frequency signal according to another embodiment of the present invention. The azimuth simulation mode of this drawing is referred to as 'fourth azimuth simulation mode (S4)', and the fourth azimuth simulation mode (S4) is an azimuth simulation for two signals generated from two independent source sources having the same fixed frequency. . The orientation simulation signal generator 10 may operate in the DDS control and switch control scenarios shown in FIG. 7 in the fourth orientation simulation mode (S4).

In the fourth azimuth simulation mode S4, two independently modulated signals must be simultaneously generated at the same frequency, and the two signals must simulate different azimuths. For this purpose, two separately provided signal generators 100a and 100b may be used. Referring to FIG. 7 , two signal flows F1 and F2 for two independent signals generated from each of the two signal generators 100a and 100b are shown by thick dotted lines.

The input selection plate 210 converts the source simulation signal received from the signal generator 100a into a first center frequency signal to be simulated through DDS1 control (frequency control), and the source simulation signal received from the other signal generator 100b. The simulation signal may be converted into a second center frequency signal through DDS2 control (frequency control) (S100). In the step of frequency control (S100) of the embodiment (S3) of this drawing, since two fixed frequency signals are used, both DDS1 control and DDS2 control are performed.

The path control step (S300) of the embodiment (S4) of this drawing is a step of controlling the path through which the input selection plate 100 receives the RF signal from the two signal generators 100a and 100b through SW2 and SW3 control ( S310), and controlling the RF path for azimuth simulation of two signals generated from two independent source sources by the phase conversion plate 220 through SW4 to SW9 control (S320).

Thereafter, simultaneous output (S400) of multi-channel azimuth simulation signals and broadband simulation signals through SW10 and SW11 control is the same as described above.

8A and 8B (hereinafter collectively referred to as 'FIG. 8') are diagrams for explaining a control sequence of a signal detection mode based on a frequency hopping signal according to another embodiment of the present invention. The simulation mode of this drawing is referred to as 'signal detection mode (S5)', and the signal detection mode (S5) is, for example, signal simulation for 20 frequency hopping signals. The azimuth simulation signal generator 10 may operate in the DDS control, switch control, and DCA control scenarios shown in FIG. 8 in the signal detection mode (S5).

The signal detection mode (S5) is a mode for detecting each single signal using 20 frequency hopping signals of 20 channels having independent phases that are not simulated with each other.

The input selection plate 210 converts the simulated source signal received from the signal generator 100 into a first fixed frequency signal to be simulated through DDS1 control (fixed frequency control), and through DDS2 control (fixed frequency control). It can be converted into a second fixed frequency signal (S100). In the step of frequency control (S100) of the embodiment (S3) of this drawing, since two frequency hopping signals are used, both DDS1 control and DDS2 control are performed. However, DDS1 and DDS2 may be controlled so that the frequencies can be independently changed based on each center frequency in order to simulate two frequency hopping signals.

Thereafter, the phase conversion plate 220 controls the first fixed frequency signal subjected to DDS1 control to have a first target hopping frequency value f1 through DDS3 control (frequency variable control) and to control through DDS4 control (frequency variable control). It can be converted to have 2 target hopping frequency values (f2). Parallel to this, the phase conversion plate 220 has a third target hopping frequency value f3 through DDS5 control (frequency variable control) for the second fixed frequency signal subjected to DDS2 control, and DDS6 control (frequency variable control) It can be converted to have a fourth target hopping frequency value (f4) through

The four frequency jumping simulated signals having f1 to f4 described above can be output through one phase conversion plate 220, and as shown in this figure, the generator 10 has five phase conversion plates 220 In the case of including 4 × 5 = 20 independent frequency hopping simulation signals can be generated.

Since the signal detection mode (S5) of this drawing is not an azimuth simulation, the phase control step (S200) can be omitted.

Subsequently, as a switch control operation, the input selection plate 210 may select the RF path of the fixed frequency signal through the control of SW3, SW4, and SW5 (S300). At this time, during step S300, the phase conversion plate 220 may implement a mute time between hopping signals through independent control of SW6, SW7, SW8, and SW9 as switch control to generate a frequency hopping signal (S510). Embodiment According to the embodiment, the phase conversion plate 220 may select an RF path for azimuth simulation based on a frequency hopping signal through SW6 to SW9 control.

On the other hand, the phase conversion plate 220 can adjust the intensity of the output signal through DCA9, DCA10 control during the step S510 (S600).

The detailed sequence of steps S300, S500 and S600 is shown in the flowchart shown on the right side of this figure.

The frequency jumping simulated signals generated as described above are transferred to the RF signal output ports of the phase conversion plate 220 that generate wideband/narrowband simulated signals through SW10 and SW11 control (RF signal path control), and then simultaneously A simulated signal may be output through the signal generating plate 230 . In this embodiment, control of SW10 and SW11 can control simulation signals to be simultaneously output to 10 channels of the surveillance output port and 10 channels of the RF signal output port.

In this way, according to the embodiments of the present invention, by generating azimuth simulation signals for each multi-channel having a required frequency and phase based on a fixed frequency signal and a frequency hopping signal, the arrival of a test signal for measuring the accuracy of a direction finding device A device capable of simulating an azimuth and an operating method thereof can be provided.

The various embodiments described in this specification are illustrative, and are not to be discriminated from and independently implemented. The embodiments described in this specification can be implemented in a form in combination with each other.

Various embodiments described above may be implemented in the form of a computer program that can be executed on a computer through various components, and such a computer program may be recorded on a computer-readable medium. In this case, the medium may continuously store a program executable by a computer or temporarily store the program for execution or download. In addition, the medium may be various recording means or storage means in the form of a single or combined hardware, and is not limited to a medium directly connected to a certain computer system, and may be distributed on a network. Examples of the medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical recording media such as CD-ROM and DVD, magneto-optical media such as floptical disks, and ROM, RAM, flash memory, etc. configured to store program instructions. In addition, examples of other media include recording media or storage media managed by an app store that distributes applications, a site that supplies or distributes various other software, and a server.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those with knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and not only the claims to be described later, but also all scopes equivalent to or equivalently changed from these claims fall within the scope of the spirit of the present invention. would be considered to be in the category.

10: Azimuth simulation signal generator
100, 100a, 100b: signal generator
110: network analyzer
120: local signal generator
200: Azimuth simulator
210: input selection board
220: phase change plate
230: simultaneous signal generating board
240: local distribution plate
250: correction path selection plate

Claims (13)

a signal generator for generating a simulated source signal in a predetermined frequency range and inputting the simulated source signal to the azimuth simulator; and
The orientation simulator for controlling at least one of the frequency, intensity, and phase of the source simulation signal to generate a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for testing,
The defense simulator,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
The operation mode of the orientation simulator is,
a first azimuth simulation mode using one fixed frequency signal;
a second azimuth simulation mode using two fixed frequency signals;
a third azimuth simulation mode using the frequency hopping simulation signal;
a fourth azimuth simulation mode using two fixed frequency signals generated from two independent sources having the same fixed frequency; and
and a signal detection mode for simultaneously outputting the frequency hopping simulation signal, the narrowband signal, and the wideband signal using at least two or more fixed frequency signals. delete a signal generator for generating a simulated source signal in a predetermined frequency range and inputting the simulated source signal to the azimuth simulator; and
The orientation simulator for controlling at least one of the frequency, intensity, and phase of the source simulation signal to generate a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for testing,
The defense simulator,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
The defense simulator,
an input selection plate for performing internal frequency up/down conversion on the simulated signal received from the signal generator and generating an IF signal including the frequency-hopping simulated signal hopping in a wide band;
a phase conversion plate that receives the IF signal generated from the input selection plate, performs frequency up/down conversion, and outputs a multi-channel azimuth simulation signal in the RF band by controlling the phase and intensity for each channel; and
Based on the multi-channel azimuth simulation signal received from the phase conversion plate, a simultaneous signal generating board that simultaneously outputs a multi-channel azimuth simulation signal and a wideband simulation signal independently phase-controlled through switch control; Mock signal generator. a signal generator for generating a simulated source signal in a predetermined frequency range and inputting the simulated source signal to the azimuth simulator; and
The orientation simulator for controlling at least one of the frequency, intensity, and phase of the source simulation signal to generate a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for testing,
The defense simulator,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
The azimuth simulation signal generator,
A network analyzer used to perform self-calibration of the azimuth simulation signal generator and checking the phase, phase control range, phase control error and phase control deviation of the input/output channel of the azimuth simulation signal generator; further comprising a direction Mock signal generator. According to claim 4,
The azimuth simulation signal generator,
A local signal generator for generating a reference signal required for the input selection plate and the phase conversion plate included in the orientation simulator, and outputting the variable frequency and signal strength of the reference signal; According to claim 5,
The defense simulator,
The reference signal is received from the local signal generator, the signal is branched, and supplied to the input selection plate and the phase conversion plate, and the reference signal and the clock signal are used together with the reference signal and the output signal generated from the internal OCXO and the PLO signal. a locally generated distribution plate for generating and transmitting to the input selection plate and the phase conversion plate; and
For self-calibration, a correction path selection plate for transmitting the correction signal for each path generated by the network analyzer through the RF path of the input selection plate and the phase conversion plate back to the network analyzer through switch control; further included. To do, azimuth simulation signal generator. Generating a simulated source signal in a predetermined frequency range to generate a simulated signal using a signal generator and inputting the simulated source signal to a direction simulator; and
Generating a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for a test by controlling at least one of frequency, intensity, and phase of the source simulation signal using the orientation simulator,
In the step of generating the target simulated signal,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
The operation mode of the orientation simulator is,
a first azimuth simulation mode using one fixed frequency signal;
a second azimuth simulation mode using two fixed frequency signals;
a third azimuth simulation mode using the frequency hopping simulation signal;
a fourth azimuth simulation mode using two fixed frequency signals generated from two independent sources having the same fixed frequency; and
and a signal detection mode for simultaneously outputting the frequency hopping simulation signal, the narrowband signal, and the wideband signal using at least two or more fixed frequency signals. delete Generating a simulated source signal in a predetermined frequency range to generate a simulated signal using a signal generator and inputting the simulated source signal to a direction simulator; and
Generating a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for a test by controlling at least one of frequency, intensity, and phase of the source simulation signal using the orientation simulator,
In the step of generating the target simulated signal,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
Generating the target simulated signal,
performing internal frequency up/down conversion on the mock signal received from the signal generator using an input selection plate, and generating an IF signal including the frequency hopping simulated signal hopping in a wide band;
receiving the IF signal generated from the input selection plate using a phase conversion plate, performing frequency up/down conversion, and outputting a multi-channel azimuth simulation signal of an RF band by controlling the phase and intensity for each channel; and
Simultaneously outputting multi-channel azimuth simulation signals and broadband simulation signals independently phase-controlled through switch control based on the multi-channel azimuth simulation signals received from the phase conversion plate using a simultaneous signal generation board; Including, a direction simulation signal generating method. Generating a simulated source signal in a predetermined frequency range to generate a simulated signal using a signal generator and inputting the simulated source signal to a direction simulator; and
Generating a target simulation signal including an orientation simulation signal and a frequency hopping simulation signal for a test by controlling at least one of frequency, intensity, and phase of the source simulation signal using the orientation simulator,
In the step of generating the target simulated signal,
Azimuth detection or signal detection function is performed using any one of a target simulation signal of a phase-controlled azimuth simulation signal, a phase-controlled frequency hopping simulation signal, and an uncontrolled frequency hopping simulation signal,
Generating the target simulated signal,
Performing self-correction of the orientation simulation signal generator using a network analyzer, and checking the phase, phase control range, phase control error, and phase control deviation of the input/output channel of the orientation simulation signal generator; further comprising , How to generate bearing simulation signals. According to claim 10,
Generating the target simulated signal,
Generating a reference signal required for an input selection plate and a phase conversion plate included in the orientation simulator using a local signal generator, and varying and outputting a frequency and signal strength of the reference signal; further comprising a direction simulation signal. how it occurs. According to claim 11,
Generating the target simulated signal,
The reference signal is received from the local signal generator using a locally generated distribution plate, and the signal is branched and supplied to the input selection plate and the phase conversion plate, and the output signal and the PLO signal generated from the internal OCXO together with the reference signal generating a reference signal and a clock signal and transmitting them to the input selection plate and the phase conversion plate; and
Transmitting the correction signal for each path generated by the network analyzer through the RF path of the input selection plate and the phase conversion plate again to the network analyzer through switch control for self-correction using a correction path selection plate. A direction simulation signal generation method further comprising; A computer program stored in a computer-readable storage medium to execute the method of any one of claims 7 and 9 to 12 using a computer.

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