CN111896952A - Multi-target deception jamming method and device based on 1-bit quantization - Google Patents

Abstract

The invention discloses a multi-target deception jamming method and a multi-target deception jamming device based on 1 bit quantization, wherein the method comprises the following steps: generating a single-frequency signal according to the false point offset and the broadband radar parameter; according to the generated single-frequency signal, carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value, and adding false point information to the quantized 1-bit signal to form a deception jamming signal; and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar. The invention realizes multi-target deception jamming while quantifying, saves computing resources compared with the conventional deception jamming, and can generate a plurality of false targets compared with the existing 1-bit deception jamming, thereby simplifying system constitution, reducing power consumption and improving efficiency.

Description

Multi-target deception jamming method and device based on 1-bit quantization

Technical Field

The invention relates to the technical field of radar signal processing, in particular to a multi-target deception jamming method and device based on 1-bit quantization, intelligent equipment and a storage medium.

Background

Synthetic Aperture radar (sar), an active earth observation system, can be installed on flight platforms such as airplanes, satellites, spacecraft, etc., and can perform earth observation all day long and all day long, and has a certain ground surface penetration capability. Therefore, the SAR system has unique advantages in disaster monitoring, environment monitoring, ocean monitoring, resource exploration, crop estimation, mapping, military and other aspects, and can play a role in which other remote sensing means are difficult to play.

The SAR (synthetic aperture radar) deception jamming machine generates a false target by delaying and modulating the phase of the intercepted SAR signal according to a pre-designed false scene, and has lower power and better jamming effect compared with the traditional jamming suppression. The jammer generates a vivid false target in a real scene, so that the information acquisition and decision of the SAR are disturbed, and therefore, research on SAR deception interference draws wide attention of scholars. However, as the false scene increases, the computational complexity and the computation time required for generating the spoofing interference also increase, which not only puts higher requirements on the cost of the jammer, but also on the real-time performance of the jammer. In order to reduce the computation amount of the SAR spoofing jammer and improve the real-time performance of spoofing interference generation, a more concise and efficient interference generation method needs to be researched.

In the prior art, when multi-target deception jamming modulation is carried out, the method has the advantages of large occupation of computing resources, high power consumption, large computation amount and complex system.

Thus, there is still a need for improvement and development of the prior art.

Disclosure of Invention

The technical problem to be solved by the present invention is to provide a multi-target deception jamming method, apparatus, intelligent device and storage medium based on 1-bit quantization, aiming at solving the problems of the prior art, such as large computing resource occupation, high power consumption, large computation and complex system when performing multi-target deception jamming modulation.

The technical scheme adopted by the invention for solving the problems is as follows:

a multi-target spoofing interference method based on 1-bit quantization, wherein the method comprises:

generating a single-frequency signal according to the false point offset and the broadband radar parameter;

according to the generated single-frequency signal, carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value, and adding false point information to the quantized 1-bit signal to form a deception jamming signal;

and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar.

The multi-target deception jamming method comprises the following steps of generating a single-frequency signal according to the false point offset and the broadband radar parameter:

and the jammer generates a single-frequency signal according to the false point offset and the broadband radar parameter.

The multi-target deception jamming method comprises the following steps of generating a single-frequency signal according to the false point offset and the broadband radar parameter:

and identifying the false point offset by taking the position of the jammer as a coordinate origin.

The multi-target deception jamming method comprises the following steps of generating a single-frequency signal according to the false point offset and the broadband radar parameter:

obtaining parameter K of broadband radar_r；

According to desired dummy pointsThe offset DeltaR generates a single-frequency signal h_sThe expression is as follows:

wherein A is_sIs the signal amplitude, K_rIn order to tune the frequency of the radar signal,

is the initial phase (which may take any constant).

The multi-target deception jamming method comprises the steps of carrying out 1-bit quantization on an intercepted broadband radar signal by using a single-frequency signal as a threshold value according to a generated single-frequency signal, and adding false point information to the quantized 1-bit signal to form a deception jamming signal:

intercepting radar signals;

the intercepted radar signal is compared with h_s(t_r) Performing IQ orthogonal sampling after comparison;

the I path sampling value is quantized into 1 bit, the Q path sampling value is quantized into 1 bit after the sign inversion, 1 bit quantization and signal conjugation are realized, and accordingly 1 bit deception jamming signals are intercepted and captured.

The multi-target deception jamming method is characterized in that deception jamming signals are forwarded to a radar, and the step of forming multi-target deception jamming in a broadband radar comprises the following steps:

directly forwarding the signals after quantitative acquisition to a radar;

and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar.

The multi-target deception jamming method comprises the steps of carrying out 1-bit quantization on an intercepted broadband radar signal by using a single-frequency signal as a threshold value according to a generated single-frequency signal, and adding false point information to the quantized 1-bit signal to form a deception jamming signal:

the generation of a plurality of false points is realized by modifying a single-frequency threshold signal and subsequent 1-bit quantization and deception jamming modulation processing;

and realizing quantization and multi-target deception jamming generation through one-time quantization.

A multi-target spoofing jamming device based on 1-bit quantization, wherein the device comprises:

the single-frequency signal generating module is used for generating a single-frequency signal according to the false point offset and the broadband radar parameter;

the 1-bit quantization module is used for carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value according to the generated single-frequency signal, and adding false point information in the quantized 1-bit signal to form a deception jamming signal;

and the multi-target deception jamming forming module is used for forwarding the deception jamming signal to the radar and forming multi-target deception jamming in the broadband radar.

An intelligent device comprising a memory, and one or more programs, wherein the one or more programs are stored in the memory, and wherein the one or more programs configured to be executed by the one or more processors comprise instructions for performing the method of any of the above.

A non-transitory computer readable storage medium having instructions therein which, when executed by a processor of an electronic device, enable the electronic device to perform a method as any one of above.

The invention has the beneficial effects that: the invention provides a multi-target deception jamming method based on 1 bit quantization. The method can carry out multi-target deception jamming on the broadband radar including the SAR radar. The jammer generates a specific single-frequency signal according to the false point offset and the broadband radar parameter, performs 1-bit quantization on the intercepted broadband radar signal by taking the signal as a threshold value, and forwards the deception jamming generated by modulation to the radar, so that the multi-target deception jamming is formed in the broadband radar. The invention realizes multi-target deception jamming while quantifying, saves computing resources compared with the conventional deception jamming, and can generate a plurality of false targets compared with the existing 1-bit deception jamming, thereby simplifying system constitution, reducing power consumption and improving efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic flow chart of a multi-target spoofing jamming method according to an embodiment of the present invention.

Fig. 2 is a comparison of distance-dimensional imaging effects of conventional spoofing interference and novel spoofing interference formed by Δ R ═ 20m in the multi-target spoofing interference method provided by the embodiment of the present invention.

Fig. 3 is a comparison of distance-dimensional imaging effects of conventional spoofing interference and novel spoofing interference formed by Δ R-40 m of the multi-target spoofing interference method provided by the embodiment of the present invention.

Fig. 4 is a schematic block diagram of a multi-target spoofing jamming device according to an embodiment of the present invention.

Fig. 5 is a schematic block diagram of an internal structure of an intelligent device according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

Radar, which finds objects and determines their spatial position by radio. Thus, radar is also referred to as "radiolocation". Radars are electronic devices that detect objects using electromagnetic waves. The radar emits electromagnetic waves to irradiate a target and receives the echo of the target, so that information such as the distance from the target to an electromagnetic wave emission point, the distance change rate (radial speed), the azimuth and the altitude is obtained.

Jammers refer to electronic devices that emit or retransmit electronic jamming signals and are used to disturb or fool hostile electronic devices, reducing or even disabling their effectiveness.

The purpose of spoofing interference is to deliberately create spurious signals. These signals are camouflaged much like those expected by an enemy device, thereby enticing the enemy to misunderstand or use the information obtained. The purpose of spoofing interference is not to suppress the disturbed system with external noise so that it cannot detect the true signal, but to deliberately create a false signal. A deception jamming can transform the radar signal and forward it to radar, so that the radar can track the fake target without existence and the real target can be protected. In addition, a large number of false targets can be formed, so that the system of the other party is difficult to obtain valuable information from the false targets, and even the data processing system of the radar is full of work and cannot work normally due to the fact that the number of the false targets is too large.

The inventor finds the problems of more computing resource occupation, high power consumption, large computation amount and more complex system when carrying out multi-target deception jamming modulation in the prior art,

in order to solve the above technical problem, an embodiment of the present invention provides a multi-target spoofing interference method based on 1-bit quantization. The method can carry out multi-target deception jamming on the broadband radar including the SAR radar. The jammer generates a specific single-frequency signal according to the false point offset and the broadband radar parameter, performs 1-bit quantization on the intercepted broadband radar signal by taking the signal as a threshold value, and forwards the deception jamming generated by modulation to the radar, so that the multi-target deception jamming is formed in the broadband radar. The invention realizes multi-target deception jamming while quantifying, saves computing resources compared with the conventional deception jamming, and can generate a plurality of false targets compared with the existing 1-bit deception jamming, thereby simplifying system constitution, reducing power consumption and improving efficiency.

Exemplary method

As shown in fig. 1, an embodiment of the present invention provides a multi-target spoofing interference method based on 1-bit quantization, where the multi-target spoofing interference method may be applied to an intelligent device, and the intelligent device may be an intelligent jammer. In the embodiment of the invention, the multi-target spoofing interference method comprises the following steps:

s100, generating a single-frequency signal according to the false point offset and the broadband radar parameter;

in the implementation of the invention, the jammer is adopted to generate a specific single-frequency signal according to the false point offset and the broadband radar parameter, for example, the identification of the false point offset is carried out by taking the position of the jammer as a coordinate origin.

In an implementation, the present invention may set a specific (or specific) single frequency signal, and perform 1-bit quantization on the acquired radar signal using the specific single frequency signal to generate a modulated spoofing interference signal. The specific implementation process is as follows:

the method comprises the following steps: the parameters of the broadband radar are obtained,

obtaining broadband radar parameters, e.g. K, e.g. by scouting, intelligence, etc_r(ii) a In this embodiment, the radar parameter is preferably a frequency modulation of a radar signal. In this embodiment, the method mainly aims at obtaining radar parameters and how to generate deception jamming signals after intercepting radar signals.

Step two: generating a single-frequency signal h according to the offset DeltaR of the desired dummy point_sThe expression is as follows:

wherein A is_sIs the signal amplitude, K_rIn order to tune the frequency of the radar signal,

is the initial phase (which may take any constant).

In the embodiment of the invention, the offset Δ R is the offset of a false target point which is expected to be generated on the enemy radar finally relative to the position of the jammer, for example, the jammer is 1km away from the radar, and if the enemy radar is expected to detect a target 1050m away, the offset is 50 m. The signal amplitude is the signal amplitude collected.

Step S200, according to the generated single-frequency signal, carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value, and adding false point information in the quantized 1-bit signal;

intercepting radar signals;

the intercepted radar signal is compared with h_s(t_r) Performing IQ orthogonal sampling after comparison; in the embodiment of the invention, IQ orthogonal sampling is a commonly used acquisition method for radar signal processing hardware, and has the effect of converting common signals into a real part and an imaginary part in a complex signal form. And complex signal processing in the algorithm is conveniently realized subsequently, wherein the I path signal is the real part of the complex signal, and the Q path signal is the imaginary part of the complex signal. The step is realized by hardware, namely IQ sampling is carried out after a signal is received, the signal is divided into IQ two paths, and then h is used for dividing the IQ two paths into H paths_s(t_r) Quantization processing is performed for the threshold value, so that 1-bit quantization of the signal can be achieved.

The I path of sampling values are quantized into 1 bit, the Q path of sampling values are quantized into 1 bit after the sign inversion, and the conjugation processing of signals is realized while the 1 bit quantization is realized. This step also adds false point information to the quantized signal for deceptive jamming modulation.

In the invention, the signal conjugation is realized by quantizing the I path of sampling values into 1 bit, and quantizing the Q path of sampling values into 1 bit after inverting the signs. The I path of sampling value is the real part of the signal, and the Q path is the imaginary part of the signal. That is, the signal is x + jy before this step and x-jy after processing, so that conjugation is realized.

In the embodiment of the invention, the I path sampling value is quantized into 1 bit, the Q path sampling value is quantized into 1 bit after the sign is inverted, and the 1 bit quantization and the signal conjugation are realized, so that the interception of the 1 bit deception jamming signal is realized.

The processed signals already contain signals of false points, and interference can be generated on an enemy radar.

And step S300, forwarding the deception jamming signal to the radar, and forming multi-target deception jamming in the broadband radar.

When the method is implemented specifically, a quantized intercepted signal can be directly forwarded to the radar, and further interference modulation can be carried out according to needs, wherein the interference modulation comprises the steps of delaying the intercepted signal, and carrying out convolution on the intercepted signal by adopting a one-dimensional distance image containing the characteristics of a false target, so that the false target is far away from an interference machine and has a vivid scattering characteristic. Wherein the time delay amount

△R₁Is the distance of the decoy from the jammer; one-dimensional range profile of

σ_wIs the reflection coefficient of the set decoy.

And forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar. As shown in the simulation results of fig. 2, the simulation results of the present invention can generate two false target points a1 and b1, whereas the conventional spoofing disturbs only one false target point.

The invention realizes the generation of a plurality of false points by modifying a single-frequency threshold signal and subsequent bit quantization and deception jamming modulation processing; and realizing quantization and multi-target deception jamming generation through one-time quantization.

Preferably, in the embodiments of the present invention, theIn practice, the radar emits a chirp of duration T_rSuppose at T_rA certain time inside is t_rFrequency of the signal at the carrier frequency f_cAs a center, with t_rIs increased by an increase of K_rAnd rect () is the rectangular envelope of the signal. The signal form is represented as follows:

expression (1) represents a chirp signal transmitted by a radar transmitter.

Jammer in-range transmitter R_JThe truncated radar signal is expressed as follows:

equation (2) represents the signal intercepted by the jammer.

Wherein tau is_JFor the delay of the radar signal from the transmitter to the jammer, the expression is as follows:

τ_J＝2R_J/c (3)

for the distance of the jammer from the transmitter

Substituting (3) into (2), and performing frequency-removing processing on the intercepted signal to obtain a signal expression as follows:

in the formula (4), the frequency carrier is removed after substituting (3) into (2), i.e. exp (j2 π f) is removed_ct_r) Item, at the same time

λ is the signal wavelength.

Quantizing the (4) type signal by using a single-frequency time-varying threshold signal can obtain an expression of the quantized signal:

s_I1(t_r)＝csign[s_I(t_r)+h_s(t_r)](5)

wherein

Order to

Wherein, the expression of (5) represents the quantization process, and the quantized signal is 1-bit data.

The formula (5) is simplified after being expanded, and can be written as follows:

in the formula of alpha₀＝1,α₁＝α₂＝...＝2。A_mnRepresenting the magnitude of the introduced harmonics, A when m + n is an even number_mnWhen m + n is an odd number, 0,

J_m(. cndot.) represents a Bessel function of order m.

Equation (6) is the result of the post-expansion reduction of equation (5), and represents the quantized signal expression.

And (6) knowing that the quantized signal is formed by mixing the original signal, the threshold signal and harmonic signals of the original signal and the threshold signal, wherein harmonic components can be selected to generate deception jamming signals. At the moment, the selected harmonic component generates a false target, and the rest harmonics generate single-frequency noise interference, so that mixed interference can be realized.

In order to make modulated signal possess good focusing imaging capability, the harmonic component in which the 1 st harmonic of original signal is participated, i.e. m is 1, is selected, so that A is_mnNon-zero, n can only take even numbers. And because when m is determined, A_mnSince the value of (a) becomes smaller as n increases, n is 2 (m is 1, and n is 0, which is the original letter)The sign component, cannot be modulated by a threshold signal). The modulation component is thus obtained as follows:

where equation (7) is a term of equation (6) and false point information is carried by the term and passed to the radar.

It can be seen from the above equation that the modulation frequency of the component is opposite to the original signal, which results in the mismatch of the matched filter, so that it needs to be conjugate to make the modulation frequency consistent with the original signal, i.e.:

s'_I1(t_r)＝csign[s_I(t_r)+h_s(t_r)]^*(8)

csign [. cndot ] in equation (8) is a sign function whose effect is to take the sign of the signal, i.e., 1-bit quantization of the signal.

Wherein the spoofed interference component is:

let theta₊＝φ+2ψ,θ_-＝φ-2ψ,θ₊Generating a false point, θ, at the set offset position_-Another dummy point is generated which is symmetrical to the set dummy point with respect to the jammer position as a center.

The above formula (9) represents the result of the conjugation process on the modulation component. This equation is actually a part (item) of equation (8) after expansion.

At theta₊Determining a single frequency threshold signal parameter for the false point modulation object, and determining theta₊The deployment is as follows:

the formula (10) includes target point information that can be analyzed after the radar receives the signal, and the target point information analyzed by the radar can be shifted by modifying related parameters in the target point information.

T in the formula (10)_rThe independent term only influences the phase of the signal, independently of the distance compression, wherein

The initial phase of the single frequency signal may be set to a constant.

Will t_rThe related items are proposed as follows:

to generate a dummy point offset Δ R, the following expression is required:

the combined type (11) and the formula (12) are simplified, and the following formula can be obtained:

the items are negligible and therefore have

Namely, the implementation of the invention sets a specific single-frequency signal, and uses the signal to carry out 1-bit quantization on the collected radar signal, thereby generating a modulated deception jamming signal. The method comprises the following implementation processes:

the method comprises the following steps: obtaining radar parameters, e.g. K, by scouting, intelligence, etc_r；

Step two: generating a single-frequency signal h according to the offset DeltaR of the desired dummy point_sThe expression is as follows:

wherein A is_sIs the signal amplitude, K_rIn order to tune the frequency of the radar signal,

is the initial phase (which may take any constant).

Step three: intercepting radar signal and mixing it with h_s(t_r) After comparison, IQ orthogonal sampling is carried out, the I path sampling value is quantized into 1 bit, and the Q path sampling value is quantized into 1 bit after the sign inversion (signal taking conjugate); (now 1-bit quantization and dummy point information attachment have been achieved).

Step four: and directly forwarding the signal after quantitative acquisition or further modulating to realize more true deception interference.

Therefore, the method has the advantages that the modulation of the deception interference is realized while the 1-bit quantization is carried out, the signal processing flow is greatly shortened, the signal processing speed is accelerated, and the reduction of the interference effect caused by the change of the radar parameters can be greatly avoided. Meanwhile, a specific single-frequency signal is easy to generate, and is easier to realize on hardware compared with the traditional method. In addition, the method finally realizes the mixed interference of single-frequency noise and false targets, so that the radar is more difficult to detect real targets or acquire error information.

The effect of the method can be further illustrated by the following simulation experiment. The simulation platform uses MATLAB (MATLAB is commercial mathematical software produced by MathWorks company in America, and is used for high-level technical computing language and interactive environment of algorithm development, data visualization, data analysis and numerical calculation, and mainly comprises two parts of MATLAB and Simulink).

The simulation parameters are as follows:

carrier frequency (GHz)	9
		Signal bandwidth (MHz)	150
Pulse width (us)	5
		Sampling rate (MHz)	300
Jammer distance (km)	10

The simulation result is shown in fig. 2, and a comparison is made between the distance-dimensional imaging effect of the conventional deception jamming and the distance-dimensional imaging effect of the novel deception jamming, wherein Δ R is 20. Wherein, the right side of fig. 2 is the imaging effect of the conventional deception jamming (HRRP high-resolution range profile); fig. 2 shows on the left the new deception jamming (HRRP high resolution range image) imaging effect of the present invention.

Taking the jammer position as the origin of coordinates facilitates identification of the ghost point offset. It can be seen from the left side of fig. 2 that the interference effect of the new spoofing interference is good, two symmetric dummy points (a1 and b1) are generated (the jammer is taken as a symmetric center), and the new spoofing interference introduces a large amount of noise (the region indicated by C in fig. 2 is noise) besides the dummy points, which is known to be single-frequency noise introduced by single-frequency threshold quantization by principle derivation.

The left graph of fig. 2 shows the result of radar imaging processing of the spoofed interfering echo generated by the present invention, a1 and b1 show two false points generated, and the right graph shows the result of the conventional method, which has only one false point (the right peak), and the result of the method has a large amount of single-frequency noise, the lower region.

Fig. 3 only modifies the offset, and the rest is similar to fig. 2.

Fig. 3 shows the simulation result after adjusting the distance offset, and it can be seen that the interference effect of the new spoofing interference is still good after adjusting the offset.

Certainly, in the specific implementation, two points are generated and are also regarded as 'deception jamming', but in order to improve the fidelity, (1) further time delay can be carried out, so that the position of the false target is not only around the original point; (2) the false target range profile is convolved with the 1-bit interception signal, so that the false target has more realistic scattering characteristics.

In summary, the present invention provides a multi-target spoofing interference method based on 1-bit quantization, which is characterized in that the generation of a plurality of false points is realized by modifying a single-frequency threshold signal and performing subsequent processing. The invention realizes the quantization and the multi-target deception jamming generation through one-time quantization, saves the 2-time quantization process of the conventional 1-bit deception jamming system by 1 time, greatly simplifies the construction of a signal processing system and reduces the cost of the system. The key to the interference generation of the present invention is the generation of a specific single frequency signal and the operation of taking the conjugate after quantization.

According to the method, the specific single-frequency threshold signal is generated by modifying the single-frequency threshold signal, the intercepted radar signal is quantized by using the specific single-frequency threshold signal, the quantized radar signal is conjugated, a false target is generated by using harmonic components in the conjugated radar signal, and single-frequency noise interference is generated by using the rest harmonics, so that mixed interference of single-frequency noise and the false target is realized, and the radar is more difficult to detect a real target or acquire error information.

According to the technical scheme, the quantization and the multi-target deception jamming generation are realized through one-time quantization, the 2-time quantization process of a conventional 1-bit deception jamming system is saved by 1 time, the composition of a signal processing system is greatly simplified, and the cost of the system is also reduced.

Exemplary device

As shown in fig. 4, an embodiment of the present invention provides a multi-target spoofing interference device based on 1-bit quantization, where the device includes:

a single-frequency signal generating module 510, configured to generate a single-frequency signal according to the false point offset and the wideband radar parameter;

a 1-bit quantization module 520, configured to perform 1-bit quantization on the intercepted wideband radar signal according to the generated single-frequency signal, using the single-frequency signal as a threshold, and add false point information to the quantized 1-bit signal to form a spoofed interference signal;

and a signal forwarding module 530, configured to forward the spoofed interference signal to the radar, so as to form multi-target spoofed interference in the broadband radar.

Based on the above embodiments, the present invention further provides an intelligent device, and a schematic block diagram thereof may be as shown in fig. 5. The intelligent device comprises a processor, a memory, a network interface, a display screen and a temperature sensor which are connected through a system bus. Wherein the processor of the smart device is configured to provide computing and control capabilities. The memory of the intelligent device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The network interface of the intelligent device is used for connecting and communicating with an external terminal through a network. The computer program is executed by a processor to implement a multi-objective spoofing interference method based on 1-bit quantization. The display screen of the intelligent device can be a liquid crystal display screen or an electronic ink display screen, and the temperature sensor of the intelligent device is arranged in the intelligent device in advance and used for detecting the operating temperature of the internal device.

It will be understood by those skilled in the art that the block diagram shown in fig. 5 is a block diagram of only a portion of the structure associated with the inventive arrangements and is not intended to limit the smart devices to which the inventive arrangements may be applied, and that a particular smart device may include more or less components than those shown, or some components may be combined, or have a different arrangement of components.

In one embodiment, a smart device is provided that includes a memory, and one or more programs, wherein the one or more programs are stored in the memory and configured to be executed by one or more processors the one or more programs include instructions for:

generating a single-frequency signal according to the false point offset and the broadband radar parameter;

according to the generated single-frequency signal, carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value, and carrying out deception jamming modulation on the quantized 1-bit signal;

and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when executed. Any reference to memory, storage, databases, or other media used in embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and bus dynamic RAM (RDRAM).

In summary, the invention discloses a multi-target deception jamming method, a multi-target deception jamming device and a storage medium based on 1 bit quantization, and the invention provides a multi-target deception jamming method based on 1 bit quantization. Multi-target spoofing interference may be performed for wideband radars, including SAR radars. The jammer generates a specific single-frequency signal according to the false point offset and the broadband radar parameter, performs 1-bit quantization on the intercepted broadband radar signal by taking the signal as a threshold value, and forwards the deception jamming generated by modulation to the radar, so that the multi-target deception jamming is formed in the broadband radar. The invention realizes multi-target deception jamming while quantifying, saves computing resources compared with the conventional deception jamming, and can generate a plurality of false targets compared with the existing 1-bit deception jamming, thereby simplifying system constitution, reducing power consumption and improving efficiency.

It is to be understood that the invention is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the invention as defined by the appended claims.

Claims (10)

1. A multi-target spoofing interference method based on 1 bit quantization is characterized by comprising the following steps:

generating a single-frequency signal according to the false point offset and the broadband radar parameter;

according to the generated single-frequency signal, carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value, and adding false point information to the quantized 1-bit signal to form a deception jamming signal;

and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar.

2. The multi-target spoof jamming method of claim 1, wherein the step of generating a single frequency signal based on the false point offset and wideband radar parameters comprises:

and the jammer generates a single-frequency signal according to the false point offset and the broadband radar parameter.

3. The multi-target spoof jamming method of claim 1, wherein the step of generating a single frequency signal based on the false point offset and wideband radar parameters comprises:

and identifying the false point offset by taking the position of the jammer as a coordinate origin.

4. The multi-target spoof jamming method of claim 1, wherein the step of generating a single frequency signal based on the false point offset and wideband radar parameters comprises:

obtaining parameter K of broadband radar_r；

Generating a single-frequency signal h according to the offset DeltaR of the desired dummy point_sThe expression is as follows:

wherein A is_sIs the signal amplitude, K_rIn order to tune the frequency of the radar signal,

is the initial phase and is constant.

5. The multi-target spoofing interference method of claim 4, wherein the step of quantizing the intercepted wideband radar signal by using the single frequency signal as a threshold according to the generated single frequency signal, and performing spoofing interference modulation on the quantized 1-bit signal comprises:

intercepting radar signals;

the intercepted radar signal is compared with h_s(t_r) Performing IQ orthogonal sampling after comparison;

the I path sampling value is quantized into 1 bit, the Q path sampling value is quantized into 1 bit after the sign inversion, 1 bit quantization and signal conjugation are realized, and therefore 1 bit deception jamming signals are intercepted and captured.

6. The multi-target spoof interference method of claim 1 wherein the step of forwarding modulated spoof interference to the radar, and wherein the step of forming multi-target spoof interference in the wideband radar comprises:

directly forwarding the signals after quantitative acquisition to a radar;

and forwarding the deception jamming signal to the radar to form multi-target deception jamming in the broadband radar.

7. The multi-target spoof interference method of claim 1, wherein the step of quantizing the intercepted wideband radar signal by using the single frequency signal as a threshold according to the generated single frequency signal, and adding dummy point information to the quantized 1-bit signal to form a spoof interference signal comprises:

the generation of a plurality of false points is realized by modifying a single-frequency threshold signal and subsequent 1-bit quantization and deception jamming modulation processing;

and realizing quantization and multi-target deception jamming generation through one-time quantization.

8. A multi-target spoofing interference apparatus based on 1-bit quantization, the apparatus comprising:

the single-frequency signal generating module is used for generating a single-frequency signal according to the false point offset and the broadband radar parameter;

the 1-bit quantization module is used for carrying out 1-bit quantization on the intercepted broadband radar signal by using the single-frequency signal as a threshold value according to the generated single-frequency signal, and adding false point information in the quantized 1-bit signal to form a deception jamming signal;

and the multi-target deception jamming forming module is used for forwarding the deception jamming signal to the radar and forming multi-target deception jamming in the broadband radar.

9. An intelligent device comprising a memory, and one or more programs, wherein the one or more programs are stored in the memory, and wherein the one or more programs being configured to be executed by the one or more processors comprises instructions for performing the method of any of claims 1-7.

10. A non-transitory computer readable storage medium having instructions therein, which when executed by a processor of an electronic device, enable the electronic device to perform the method of any one of claims 1-7.

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