A Method for Testing the Uncertainty of Radio Frequency Stealth Signals
A technology of uncertainty and radio frequency stealth, applied in the field of radio frequency stealth, can solve the problems of few radio frequency stealth signals, can not truly and objectively reflect the uncertainty of radio frequency stealth signals, and the objectivity is not obvious, and achieve the effect of easy realization
Active Publication Date: 2020-11-03
NANJING UNIV OF AERONAUTICS & ASTRONAUTICS
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[0005] Uncertainty testing of radio frequency stealth signals is a new field of research. Many literatures mainly focus on the time-width-bandwidth product method of radio frequency stealth signals and the peak-to-average ratio of common time-spectrum, and directly establish the uncertainty of radio frequency stealth signals with Gaussian white noise Relatively few studies have compared
The time-width-bandwidth product method and the peak-to-average ratio of the common time-spectrum are difficult to take into account various upgraded or new algorithms of passive detection systems. The uncertainty test of radio frequency stealth signals is subjective, and the objectivity is not obvious, so it cannot Truly and objectively reflect the uncertainty of radio frequency stealth signals
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[0045] A method for testing the uncertainty of radio frequency stealth signals, such as figure 1 As shown, it specifically includes the following steps:
[0046] 1. Determine the signal sequence to be tested and sort it randomly
[0047] Determine the bandwidth of the signal x(n) to be tested, and sample x(n) according to the Nyquist sampling theorem. When the number of sampling points N is not less than 30, randomly sort the sampled data to obtain a new time series x(i 1 ), x(i 2 ),…,x(i N ), where i 1 2 N .
[0048] 2. Add Gaussian white noise and calculate the number of turning points
[0049] According to the requirement of the turning point calculation principle of white noise, a predetermined ratio of Gaussian white noise is added to the original sampling signal, and the sequence x(i 1 ), x(i 2 ),…,x(i N ), the number of turning points T, the calculation expression for the number of turning points is:
[0050]
[0051]
[0052] where x i Represents the i-...
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The invention discloses a method for testing the uncertainty of a radio frequency stealth signal. The method comprises the following steps: firstly determining a to-be-tested signal sequence and a total number of sampling points, and randomly sorting the same; when the total number of sampling points is not less than the minimum total number of sampling points required by the test method, adding apreset proportion of Gaussian white noise to an original sampling signal, and calculating the number of turning points in the sampling points; performing Z detection with a confidence degree of 95% on the number of turning points; when the Z detection contrast result difference is obvious, continuing to add the preset proportion of Gaussian white noise to the original sampling signal, calculatingthe number of turning points in the sampling points again, and performing the Z detection with the confidence degree of 95% on the number of turning points until the Z detection contrast results haveno obvious difference; and repeating the process for multiple times, and using an average proportional relation between the original signal power of every Z detection and the Gaussian white noise power spectral density as a characterization index for testing the uncertainty of the radio frequency stealth signal. The method disclosed by the invention can be used for evaluating the relative uncertainty between various radio frequency stealth signals.
Description
technical field [0001] The invention relates to radio frequency stealth technology, in particular to a method for testing the uncertainty of radio frequency stealth signals. Background technique [0002] With the increasingly fierce electronic countermeasures in the modern battlefield, the detection ability of the enemy's passive detection system for radio frequency radiation signals is getting stronger and stronger, which poses a serious threat to the survival of radio frequency radiation signal equipment. The design of radio frequency stealth signal can significantly reduce the probability of the signal being detected by the enemy's passive detection system, which is an important guarantee for improving the battlefield survivability and combat effectiveness of radio frequency radiation equipment and its carrier platform. Compared with the traditional signal design technology, the radio frequency stealth signal design should reduce the interception detected by the enemy's p...
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IPC IPC(8): H04B17/00
CPCH04B17/00
Inventor 汪飞陈军时晨光李海林周建江
Owner NANJING UNIV OF AERONAUTICS & ASTRONAUTICS