CN111337885A - Radar and communication combined system radio frequency stealth performance optimization method - Google Patents

Abstract

The invention discloses a method for optimizing radio frequency stealth performance of a radar and communication combined system, which comprises the following steps: acquiring frequency response prior information of a target detection channel and frequency response of a communication channel; respectively constructing a mutual information expression representing the estimation performance of the target parameter and a data transmission rate expression representing the communication performance; constructing a radio frequency stealth optimization model of a radar and communication combined system; and solving a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar transmitting waveform and optimal communication transmitting power distribution. The method provided by the invention can minimize the total transmitting power of a radar and communication combined system by optimizing the design of radar transmitting waveform and communication transmitting power distribution under the condition of considering the estimation of a predetermined mutual information threshold value parameter and certain communication data rate delivery information, thereby improving the radio frequency stealth performance of the system.

Description

Radar and communication combined system radio frequency stealth performance optimization method

Technical Field

The invention relates to a radar waveform design technology, in particular to a method for optimizing radio frequency stealth performance of a radar and communication combined system.

Background

With the rapid development of computer technology, radar communication technology and integrated circuit technology, the combined radar and communication system has received great attention. The radar and communication combined system can simultaneously estimate the environmental parameters from the radar return signals and decode the received communication signals, and the performance of the radar and communication combined system can obviously reduce the probability that the radar is detected, found and identified by passive electronic reconnaissance equipment and attacked by anti-radiation missiles in the design stage, thereby improving the battlefield viability and the operational efficiency of the radar and a carrying platform thereof.

Currently, two main aspects are considered in the research on the performance optimization method of the radar and communication combined system: the target parameter estimation performance of the radar and the communication performance of the base station are the first. And evaluating the performance of the radar and the communication by respectively using the positioning information rate and the communication data rate, and maximizing the performance of the radar and communication combined system by optimizing the radar waveform design under the given constraint condition.

Although the methods for optimizing the performance of the radar and communication combined system are provided, the target detection performance and the parameter estimation performance of the system in the clutter environment are improved, but the methods do not consider the optimization design based on the radio frequency stealth performance in the radar and communication combined system.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects in the prior art, the invention provides a method for optimizing the radio frequency stealth performance of a radar and communication combined system, which reduces the total transmitting power of the radar and communication combined system and improves the radio frequency stealth performance of the system.

The technical scheme is as follows: in order to realize the purpose, the invention adopts the following technical scheme:

a radio frequency stealth performance optimization method for a radar and communication combined system comprises the following steps:

(1) acquiring a target detection channel frequency response and a communication channel frequency response;

(2) respectively constructing a mutual information expression representing the estimation performance of the target parameter and a data transmission rate expression representing the communication performance;

(3) constructing a radio frequency stealth optimization model of a radar and communication combined system;

(4) and solving a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar transmitting waveform and optimal communication transmitting power distribution.

Further, in the step (1), a target detection channel frequency response and a communication channel frequency response on each sub-band are obtained according to the priori knowledge.

Further, mutual information I for representing target parameter estimation performance in step (2)_radThe expression is as follows:

wherein, K_rad＝B_radΔ f is the number of sub-bands in the radar band, B_radFor radar bandwidth,. DELTA.f for subband spacing, T_yFor the duration of the signal, H_rad(f_k) For sub-band f_kFrequency response of upper target sounding channel, | R (f)_k)²For sub-band f_kEnergy spectral density, | P, of radar emission signal_nn(f_k)²For sub-band f_kThe power spectral density of the signal transmitted by the radar;

data transmission rate R characterizing communication performance_comThe expression is as follows:

wherein, K_com＝B_comΔ f is the number of communication band sub-bands, B_comFor the communication frequency bandwidth, H_com(f_k) Is a sub-band f_kFrequency response of communication channel, P_com(f_k) Is a sub-band f_kThe energy spectral density of the transmitted signal of the communication,

is a sub-band f_kNoise power of receiver, k₀Is the Boltzmann constant, T₀Is the receiver noise temperature.

Further, in the step (3), considering the target parameter estimation mutual information of the radar system and the constraint condition of the data transmission rate of the communication system, establishing a radio frequency stealth optimization model of the radar and communication combined system as follows:

and

wherein, K is_rad＝B_radΔ f is the number of sub-bands in the radar band, B_radFor radar bandwidth, | R (f) is the sub-band spacing, | F_k)²For sub-band f_kThe power spectral density of the signal transmitted by the radar; i_radMutual information characterizing the performance of the target parameter estimation,

indicating a predetermined target parameter estimation performance threshold, K_com＝B_comΔ f is the number of communication band sub-bands, B_comFor the communication frequency bandwidth, P_com(f_k) Is a sub-band f_kEnergy spectral density of the transmitted signal of (1)_comTo characterize the data transfer rate of the communication performance,

indicating a pre-set communication data rate threshold,

representing a maximum communication transmit power threshold on each sub-band.

Further, the method for solving the radio frequency stealth optimization model of the radar and communication combined system in the step (4) comprises the following steps:

(41) solving an optimization problem formula (3) of a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar emission waveform;

introducing lagrange multiplier mu_iIs not less than 0 and not less than ξ, constructed asLagrange multiplier below:

wherein, T_yFor the duration of the signal, H_rad(f_k) For sub-band f_kUpper target sounding channel frequency response, | P_nn(f_k)|²For sub-band f_kThe power spectral density of the signal transmitted by the radar;

respectively to | R (f)_k)|²，μ_iAnd ξ, calculating a partial derivative, and simultaneously:

while satisfying | R (f)_k)|²Not less than 0 and Carrocon-Cohn-Tak necessary condition, and obtaining sub-band f_kEnergy spectral density of radar emission signal | R (f)_k)|²The expression is as follows:

wherein the content of the first and second substances,

the parameter A (- ξ). T_y·Δf；

(42) Solving an optimization problem formula (4) of a radio frequency stealth optimization model of the radar and communication combined system to obtain optimal communication transmitting power distribution;

introducing a Lagrange multiplier phi_1,k≥0，φ_2,kNot less than 0 and phi₃And (3) more than or equal to 0, constructing the following Lagrangian multiplier:

wherein, P_maxIn order to be the maximum transmission power value,

is a sub-band f_kNoise power of receiver, k₀Is the Boltzmann constant, T₀Is the receiver noise temperature, H_com(f_k) Is a sub-band f_kFrequency response of the communication channel;

are respectively aligned with phi_1,k，φ_2,kAnd phi₃Calculating a partial derivative, and simultaneously ordering:

simultaneously satisfies 0 ≤ P_com(f_k)≤P_maxAnd the necessary condition of Carlo needs-Cohen-Tak, and obtaining the optimal communication transmission power expression as follows:

wherein the content of the first and second substances,

parameter C ═ phi₃·Δf。

Has the advantages that: compared with the prior art, the invention has the following beneficial effects:

(1) according to the invention, under the condition of meeting a certain target parameter estimation mutual information threshold and a communication data transmission rate threshold, the total transmitting power of the radar and communication combined system is effectively reduced by optimizing the design of the radar transmitting waveform and the communication transmitting power distribution, so that the radio frequency stealth performance of the radar and communication combined system is improved.

The method has the advantages that the requirements of the given target parameter estimation performance and the data transmission rate are met, and the total transmission power of the radar and communication combined system is effectively reduced. The method adopts the method for optimizing the radio frequency stealth performance of the radar and communication combined system, takes the preset target parameter estimation mutual information threshold and the communication data transmission rate threshold as constraint conditions, takes the minimum total transmitting power of the radar and communication combined system as an optimization target, establishes a radar and communication combined system radio frequency stealth performance optimization design model, and optimizes radar waveform design and communication power distribution. By solving the radar transmitting waveform and communication power distribution result obtained by the optimization model, the total transmitting power of the radar and communication combined system can be effectively reduced and the radio frequency stealth performance of the radar and communication combined system can be improved under the condition that a certain target parameter estimation mutual information threshold and a communication data transmission rate threshold are met.

(2) Compared with the prior art, the method for optimizing the radio frequency stealth performance of the radar and communication combined system not only meets the preset target parameter estimation performance and communication transmission rate requirements, but also improves the radio frequency stealth performance of the system.

Drawings

FIG. 1 is a flow chart of the method of the present invention.

Detailed Description

The technical solution of the present invention is described in detail below with reference to the accompanying drawings and specific embodiments.

According to the method for optimizing the radio frequency stealth performance of the radar and communication combined system, under the condition that the preset mutual information threshold parameter estimation and certain communication data rate delivery information are considered, the total transmitting power of the radar and communication combined system is minimized by optimizing the radar transmitting waveform design and the communication transmitting power distribution, and therefore the radio frequency stealth performance of the system is improved. Specifically, the method comprises the following steps:

as shown in fig. 1, a method for optimizing radio frequency stealth performance of a radar and communication combined system includes the following steps:

1. and acquiring the frequency response of the target detection channel and the frequency response of the communication channel.

And acquiring the frequency response of the target detection channel and the frequency response of the communication channel on each sub-band according to the prior knowledge.

2. And respectively constructing a mutual information expression representing the estimation performance of the target parameters and a data transmission rate expression representing the communication performance.

Mutual characterization of target parameter estimation performance of radar and communication combined systemInformation (i.e. mutual information characterizing the estimation performance of the target parameter) I_radThe expression is as follows:

wherein, T_yFor the duration of the signal, K_rad＝B_radΔ f is the number of sub-bands in the radar band, B_radFor radar bandwidth,. DELTA.f for subband spacing, H_rad(f_k) For sub-band f_kFrequency response of upper target sounding channel, | R (f)_k)|²For sub-band f_kEnergy spectral density, | P, of radar emission signal_nn(f_k)|²For sub-band f_kThe power spectral density of the transmitted signal.

Data transmission rate (i.e. data transmission rate for characterizing communication performance) R for characterizing communication performance of radar and communication combined system_comThe expression is as follows:

wherein, K_com＝B_comΔ f is the number of communication band sub-bands, B_comFor the communication frequency bandwidth, H_com(f_k) Is a sub-band f_kFrequency response of communication channel, P_com(f_k) Is a sub-band f_kThe energy spectral density of the transmitted signal of the communication,

is a sub-band f_kNoise power of receiver, k₀Is the Boltzmann constant, T₀Is the receiver noise temperature.

3. And constructing a radio frequency stealth optimization model of the radar and communication combined system.

Considering the target parameter estimation mutual information of the radar system and the constraint condition of the data transmission rate of the communication system, and establishing a radio frequency stealth optimization model of the radar and communication combined system as follows:

and

wherein the content of the first and second substances,

indicating a pre-set target parameter estimation performance threshold,

indicating a pre-set communication data rate threshold,

representing a maximum communication transmit power threshold on each sub-band.

4. Solving the radio frequency stealth optimization model of the radar and communication combined system in the step 3 to obtain an optimal radar transmitting waveform and optimal communication transmitting power distribution; the method specifically comprises the following steps:

4.1, solving an optimization problem formula (3) of a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar emission waveform;

introducing lagrange multiplier mu_iAnd more than or equal to 0 and ξ more than or equal to 0, constructing the following Lagrange multiplier:

respectively to | R (f)_k)|²，μ_iAnd ξ, calculating a partial derivative, and simultaneously:

while satisfying | R (f)_k)|²Obtaining sub-bands based on requirements of not less than 0 and Carrocon-Kuhn-Tucker (KKT)f_kEnergy spectral density of radar emission signal | R (f)_k)|²The expression is as follows:

wherein the content of the first and second substances,

the parameter A (- ξ). T_y·Δf。

4.2, solving an optimization problem formula (4) of a radio frequency stealth optimization model of the radar and communication combined system to obtain optimal communication transmitting power distribution;

introducing a Lagrange multiplier phi_1,k≥0，φ_2,kNot less than 0 and phi₃And (3) more than or equal to 0, constructing the following Lagrangian multiplier:

wherein, P_maxIs the maximum transmit power value. Are respectively aligned with phi_1,k，φ_2,kAnd phi₃Calculating a partial derivative, and simultaneously ordering:

simultaneously satisfies 0 ≤ P_com(f_k)≤P_maxAnd KKT necessary conditions, and obtaining an optimal communication transmitting power expression as follows:

wherein the content of the first and second substances,

parameter C ═ phi₃·Δf。

The working principle and the working process of the invention are as follows:

firstly, aiming at a radar and communication combined system, acquiring target detection channel frequency response and communication channel frequency response on each sub-frequency band according to prior knowledge; then, respectively constructing a mutual information expression representing the estimation performance of the target parameters and a data transmission rate expression representing the communication performance; on the basis, a preset target parameter estimation mutual information threshold and a communication data transmission rate are met as constraint conditions, the total emission power of the radar and communication combined system is minimized as an optimization target, a radar and communication combined system radio frequency stealth performance optimization design model is established, and radar emission waveform design and communication emission power distribution are optimized. By adopting a Lagrange multiplier method and KKT necessary conditions, the optimal radar transmitting waveform and optimal communication transmitting power distribution are obtained by solving the optimization model, the total transmitting power of the radar and communication combined system can be effectively reduced under the condition that a certain target parameter estimation performance mutual information threshold value and a certain data transmission rate threshold value are met, and the radio frequency stealth performance of the radar and communication combined system is improved.

Claims (5)

1. A radio frequency stealth performance optimization method for a radar and communication combined system is characterized by comprising the following steps:

(1) acquiring a target detection channel frequency response and a communication channel frequency response;

(2) respectively constructing a mutual information expression representing the estimation performance of the target parameter and a data transmission rate expression representing the communication performance;

(3) constructing a radio frequency stealth optimization model of a radar and communication combined system;

(4) and solving a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar transmitting waveform and optimal communication transmitting power distribution.

2. The method for optimizing the radio frequency stealth performance of the radar and communication combined system according to claim 1, wherein in the step (1), the frequency response of the target detection channel and the frequency response of the communication channel on each sub-band are obtained according to a priori knowledge.

3. According to claim1, the method for optimizing radio frequency stealth performance of radar and communication combined system is characterized in that mutual information I for representing target parameter estimation performance in step (2)_radThe expression is as follows:

wherein, K_rad＝B_radΔ f is the number of sub-bands in the radar band, B_radFor radar bandwidth,. DELTA.f for subband spacing, T_yFor the duration of the signal, H_rad(f_k) For sub-band f_kFrequency response of upper target sounding channel, | R (f)_k)|²For sub-band f_kEnergy spectral density, | P, of radar emission signal_nn(f_k)|²For sub-band f_kThe power spectral density of the signal transmitted by the radar;

data transmission rate R characterizing communication performance_comThe expression is as follows:

wherein, K_com＝B_comΔ f is the number of communication band sub-bands, B_comFor the communication frequency bandwidth, H_com(f_k) Is a sub-band f_kFrequency response of communication channel, P_com(f_k) Is a sub-band f_kThe energy spectral density of the transmitted signal of the communication,

is a sub-band f_kNoise power of receiver, k₀Is the Boltzmann constant, T₀Is the receiver noise temperature.

4. The method for optimizing the radio frequency stealth performance of the radar and communication combined system according to claim 1, wherein in the step (3), the target parameter estimation mutual information of the radar system and the constraint condition of the data transmission rate of the communication system are considered, and the radio frequency stealth optimization model of the radar and communication combined system is established as follows:

and

wherein, K is_rad＝B_radΔ f is the number of sub-bands in the radar band, B_radFor radar bandwidth, | R (f) is the sub-band spacing, | F_k)|²For sub-band f_kThe power spectral density of the signal transmitted by the radar; i_radMutual information characterizing the performance of the target parameter estimation,

indicating a predetermined target parameter estimation performance threshold, K_com＝B_comΔ f is the number of communication band sub-bands, B_comFor the communication frequency bandwidth, P_com(f_k) Is a sub-band f_kEnergy spectral density of the transmitted signal of (1)_comTo characterize the data transfer rate of the communication performance,

indicating a pre-set communication data rate threshold,

representing a maximum communication transmit power threshold on each sub-band.

5. The method for optimizing the radio frequency stealth performance of the radar and communication combined system according to claim 4, wherein the method for solving the radio frequency stealth optimization model of the radar and communication combined system in the step (4) comprises the following steps:

(41) solving an optimization problem formula (3) of a radio frequency stealth optimization model of the radar and communication combined system to obtain an optimal radar emission waveform;

introducing lagrange multiplier mu_iAnd more than or equal to 0 and ξ more than or equal to 0, constructing the following Lagrange multiplier:

wherein, T_yFor the duration of the signal, H_rad(f_k) For sub-band f_kUpper target sounding channel frequency response, | P_nn(f_k)|²For sub-band f_kThe power spectral density of the signal transmitted by the radar;

respectively to | R (f)_k)|²，μ_iAnd ξ, calculating a partial derivative, and simultaneously:

while satisfying | R (f)_k)|²Not less than 0 and Carrocon-Cohn-Tak necessary condition, and obtaining sub-band f_kEnergy spectral density of radar emission signal | R (f)_k)|²The expression is as follows:

wherein the content of the first and second substances,

the parameter A (- ξ). T_y·Δf；

(42) Solving an optimization problem formula (4) of a radio frequency stealth optimization model of the radar and communication combined system to obtain optimal communication transmitting power distribution;

introducing a Lagrange multiplier phi_1,k≥0，φ_2,kNot less than 0 and phi₃And (3) more than or equal to 0, constructing the following Lagrangian multiplier:

wherein, P_maxIn order to be the maximum transmission power value,

is a sub-band f_kNoise power of receiver, k₀Is the Boltzmann constant, T₀Is the receiver noise temperature, H_com(f_k) Is a sub-band f_kFrequency response of the communication channel;

are respectively aligned with phi_1,k，φ_2,kAnd phi₃Calculating a partial derivative, and simultaneously ordering:

simultaneously satisfies 0 ≤ P_com(f_k)≤P_maxAnd the necessary condition of Carlo needs-Cohen-Tak, and obtaining the optimal communication transmission power expression as follows:

wherein the content of the first and second substances,

parameter C ═ phi₃·Δf。

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