CN111398928A - Method for calculating detection threshold of synthetic ultra-narrow pulse radar based on resampling algorithm - Google Patents
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Abstract
The invention provides a method for calculating a detection threshold of a synthetic ultra-narrow pulse radar based on a resampling algorithm.
Description
Technical Field
The invention relates to the technical field of target detection, in particular to a method for calculating a detection threshold of a synthetic ultra-narrow pulse radar based on a resampling algorithm.
Background
At present, there are radar detection algorithms such as an integral detector, an MN detector, an SSD-G L RT (Spatial Scattering Density-Generalized L Ikeliod Ratio Test) detector, a sequential detector and the like, but detectors such as SSD-G L RT, sequential detectors and the like are difficult to calculate detector thresholds by an analytical method because the distribution of the Test statistic obeys is difficult to calculate.
To obtain the threshold of such detectors, it is conventional to generate enough ambient noise signals, input them to the detector to obtain test statistics, and sort the samples from small to large to determine the detector threshold corresponding to the false alarm rate. The method needs to store a large amount of random numbers, has the defects of high memory occupation and low threshold calculation speed of the detector.
Disclosure of Invention
The invention provides a method for calculating a detection threshold of a synthetic ultra-narrow pulse radar based on a resampling algorithm, which aims to overcome the defect that a large number of random numbers need to be stored and occupy a memory in the traditional method and improve the calculation speed of the detector threshold.
In order to solve the technical problem, the invention provides a method for calculating a detection threshold of a synthetic extremely-narrow pulse radar based on a resampling algorithm, which comprises the following steps:
step one, inputting the number N of test statistics and arranging the false alarm rate into p in the order from large to small1,p2,...,pMThe detector window length is L;
step two, the resampling random sample generator generates N windows with the length of L and the probability density function of f1Of the noise signal xn={x1,x2,...,xL},n=1,2,...,N;;
Step three, calculating the weight corresponding to the nth noise sample;
Step four, generating N test statistics T according to the judgment rule of the detectorn(x),n=1,2,...,N;
Step five, initializing a quantile generator, setting (2M +3) quantiles, and sequencing the first (2M +3) test statistics in a sequence from small to large to obtain a sequence statistic T(i)I 1, 2., (2M +3), calculated to yield T(i)Corresponding sample weight wiFor the size q of the ith quantile valueiRepresents the number n of accumulated samples corresponding to the ith quantileiSample increment Δ n corresponding to time-division bit points when the algorithm executes sequentiallyiAnd represents the desired number of samples n 'for the ith quantile'iThe following assignment operations are performed:
qi=T(i),i=1,2,...,(2M+3);
n′i=1+2(M+1)Δni;
step six, inputting the jth test statistic Tj(x) Performing iterative update of a threshold, wherein j > (2M + 3);
step seven, outputting q2m+1As false alarm rate pm(M1, 2.. times.m) corresponds to an estimate of the threshold.
Further, the sixth step includes:
a) will Tj(x) And q isiI 1, 2., (2M +3) are compared and T is determinedj(x) Returning to the intermediate variable k when the interval is Tj(x)<q1Or Tj(x)>q2M+3When q is updated1Or q2M+3;
b) Updating niAnd n'i:
ni=ni+wi,i=k,...,2M+3;
n′i=n′i+Δn′i,i=1,...,2M+3;
c) Adjusting the threshold corresponding to the (2M +2) th component site:
d=n′i-ni,i=2,...,2M+2;
dl=ni-1-ni;dr=ni+1-ni;
if (d is not less than 1 and drGreater than 1) or (d is less than or equal to-1 and d isr< -1 >), then order
d′=sign(d);
If q isi-1<q′i<q i+1, let the ith threshold and the number of samples be:
qi=q′i;
ni=n′i;
otherwise
ni=n′i。
Further, the step a) comprises:
at Tj(x) In the interval of Tj(x)<q1Then, the intermediate variable k is returned to 1, and q is updated1=Tj(x);
At Tj(x) In the interval q1≤Tj(x)<q2If yes, returning an intermediate variable k to be 1;
at Tj(x) In the interval q2≤Tj(x)<q3If yes, returning an intermediate variable k to be 2; ...;
at Tj(x) In the interval q2M+2≤Tj(x)<q2M+3If yes, returning an intermediate variable k which is 2M + 2;
at Tj(x) In the interval q2M+3<Tj(x) Then, the intermediate variable k is returned to 2M +2, and q is updated2M+3=Tj(x)。
The invention has the beneficial effects that:
according to the method for calculating the detection threshold of the synthetic ultra-narrow pulse radar based on the resampling algorithm, random samples are generated through resampling, and the threshold corresponding to each false alarm rate of the detector is determined simultaneously by using the quantile interpolation algorithm, so that the defect that a large amount of random numbers need to be stored to occupy an internal memory in the traditional method is overcome, and the calculation speed of the threshold of the detector is improved.
Drawings
Fig. 1 is a schematic flow chart of a synthetic ultra-narrow pulse radar detection threshold calculation method based on a resampling algorithm according to an embodiment of the present invention;
FIG. 2 is a schematic view of an iterative update process according to a first embodiment of the present invention;
fig. 3 is a schematic diagram of threshold update of the SSD-G L RT detector according to the first embodiment of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following detailed description and accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
The first embodiment is as follows:
in order to solve the problems that a large number of random numbers need to be stored, the memory occupation is high and the threshold calculation speed of the detector is low in the traditional threshold determination mode, a quantile point interpolation algorithm is utilized. By setting the quantiles corresponding to the false alarm rate and calling an interpolation algorithm to iteratively update the corresponding thresholds of the quantiles according to the input test statistic, the defect that the traditional method for determining the quantiles by sequencing needs to store a large number of random numbers to occupy a memory is overcome.
The re-sampling enables the sampling algorithm to generate more samples contributing to the calculation of the false alarm rate by changing the probability distribution of the generated random numbers, further reduces the number of the generated samples required for accurately counting the false alarm probability, and improves the threshold acquisition speed of the detector.
The invention assumes that the environmental noise is additive complex Gaussian white noise and the noise power is sigma2With a probability density function of f0The method provided by the invention is shown in figure 1 and mainly comprises the steps of resampling to generate random samples, calculating sample weight, generating test statistic, initializing a dynamic quantile generator, updating a threshold and outputting the threshold. The method comprises the following specific steps:
step one, inputting the number N of test statistics and arranging the false alarm rate into p in the order from large to small1,p2,...,pMThe detector window length is L;
step two, the resampling random sample generator generates N windows with the length of L and the probability density function of f1Of the noise signal xn={x1,x2,...,xL},n=1,2,...,N
Step three, calculating the weight corresponding to the nth noise sample;
Step four, generating N test statistics T according to the judgment rule of the detectorn(x),n=1,2,...,N;
Step five, initializing a quantile generator, setting (2M +3) quantiles, and sequencing the first (2M +3) test statistics in a sequence from small to large to obtain a sequence statistic T(i)I 1, 2., (2M +3), calculated to yield T(i)Corresponding sample weight wiFor the size q of the ith quantile valueiRepresents the number n of accumulated samples corresponding to the ith quantileiSample increment Δ n corresponding to time-division bit points when the algorithm executes sequentiallyiAnd represents the desired number of samples n 'for the ith quantile'iThe following assignment operations are performedThe method comprises the following steps:
qi=T(i),i=1,2,...,(2M+3);
n′i=1+2(M+1)Δni;
step six, inputting the jth test statistic Tj(x) Performing iterative update of a threshold, wherein j > (2M + 3);
step seven, outputting q2m+1As false alarm rate pm(M1, 2.. times.m) corresponds to an estimate of the threshold.
Wherein, step six includes:
a) will Tj(x) And q isiI 1, 2., (2M +3) are compared and T is determinedj(x) Returning to the intermediate variable k when the interval is Tj(x)<q1Or Tj(x)>q2M+3When q is updated1Or q2M+3(ii) a See table 1 below:
TABLE 1
At Tj(x) In the interval of Tj(x)<q1Then, the intermediate variable k is returned to 1, and q is updated1=Tj(x);
At Tj(x) In the interval q1≤Tj(x)<q2If yes, returning an intermediate variable k to be 1;
at Tj(x) In the interval q2≤Tj(x)<q3When the intermediate variable k is returned to2;......;
At Tj(x) In the interval q2M+2≤Tj(x)<q2M+3If yes, returning an intermediate variable k which is 2M + 2;
at Tj(x) In the interval q2M+3<Tj(x) Then, the intermediate variable k is returned to 2M +2, and q is updated2M+3=Tj(x)。
b) Updating niAnd n'i:
ni=ni+wi,i=k,...,2M+3;
n′i=n′i+Δn′i,i=1,...,2M+3;
c) Adjusting the threshold corresponding to the (2M +2) th component site:
d=n′i-ni,i=2,...,2M+2;
dl=ni-1-ni;dr=ni+1-ni;
if (d is not less than 1 and drGreater than 1) or (d is less than or equal to-1 and d isr< -1 >), then order
d′=sign(d);
If q isi-1<q′i<qi+1Let the ith threshold and the number of samples be:
qi=q′i;
ni=n′i;
otherwise
ni=n′i。
The following gives a simulation example to which the present invention is applied, and analyzes and explains the threshold determination process.
SSD-G L RT detector is the energy accumulation detection method based on scattering point space Density weighting (SSD). SSD-G L RT detector needs to know the prior parameter α of the target scattering point Density, and then reduces the influence of range unit echoes containing weak scattering points or non-scattering points on the detection performance of the detector by weighting the echoes of each range unit in a detection window.A method for solving the test statistic of the SSD-G L RT detector comprises the following steps:
xirepresents the modulo square of the i-th range bin echo data within the detection window, at H0Let x beiObeying an exponential distribution with a mean value of 1, xn={x1,x2,...,xL1, 2, the probability density function of N can be expressed as:
the SSD-G L RT detector has no threshold calculation formula because it is difficult to find the likelihood function of the SSD-G L RT detector test statistic T (x).
To find the threshold, the conventional method is at H0Assuming that L× N random numbers are generated, the test statistic T of each simulation is obtained by the decision rulei(x) 1, 2, N, and mixing Ti(x) Arranged in the order of T from small to large(1),T(2),…,T(N)A decision of H is determined by the false alarm probability1T ofi(x) The upper limit of the number U, and the sum of the number T(N-U)The corresponding value is used as the detection threshold.
According to the invention, the threshold solving process comprises the following steps:
step one, determining the number N of input test statistics to be 105The false alarm rate p is 0.1, and the window length L is 10;
step two, the resampling random sample generator generates N groups of data x with window length of L and obeying exponential distribution with mean value of 2n={x1,x2,...,xL1, 2, N, whose probability distribution can be expressed as:
step three, calculating the weight of each noise sample:
and step four, setting the prior parameter α of the scattering point density to be 0.1, and generating N test statistics T according to the judgment rule of the detectorn(x),n=1,2,...,N;
Step five, initializing the dynamic quantile generator, and sequencing the test statistics input in the first five times in a sequence from small to large to obtain a sequence statistic T (i)1, 2, 5, find the generation T(i)Weight w of corresponding sampleiAs shown in table 2 below:
TABLE 2
i | 1 | 2 | 3 | 4 | 5 |
T(i) | 7.6977 | 7.7678 | 7.9533 | 8.4929 | 11.0927 |
wi | 0.0843 | 0.0642 | 0.9472 | 0.0334 | 0.0371 |
To q isi,ni,Δni,n′iPerforming assignment operation, as shown in the following table 3:
TABLE 3
Step six, after the initialization of the dynamic quantile generator is completed, continuously inputting the test statistic to carry out the iterative update of the threshold, wherein the iterative process is shown in figure 2;
in the simulation example, only 1 false alarm corresponding threshold is required, M is 1, 2M +3 is 5 quantiles q, so the 3 rd quantile q is taken3As a detection threshold. Above table q37.9533 is the initial assignment, updating quantile q through six iterations of step3To obtain q3The final value is 5.5984, q in the updating process3See fig. 3 for values of (a).
Step seven, outputting (1-p) -quantile point q3The final value 5.5984 is taken as the estimate of the false alarm probability p for the threshold.
The obtained threshold is verified by Monte Carlo simulation, the SSD _ G L RT detector generates 1e5 test statistics, the comparison with the threshold 5.5984 is carried out, the obtained false alarm rate is 0.1002, and the correctness of the method can be verified.
It will be apparent to those skilled in the art that the steps of the present invention described above may be implemented in a general purpose computing device, centralized on a single computing device or distributed across a network of computing devices, or alternatively, in program code executable by a computing device, such that the steps shown and described may be performed by a computing device stored on a computer storage medium (ROM/RAM, magnetic or optical disk), and in some cases, performed in a different order than that shown and described herein, or separately fabricated into individual integrated circuit modules, or fabricated into a single integrated circuit module from multiple ones of them. Thus, the present invention is not limited to any specific combination of hardware and software.
The foregoing is a more detailed description of the present invention that is presented in conjunction with specific embodiments, and the practice of the invention is not to be considered limited to those descriptions. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.
Claims (3)
1. The method for calculating the detection threshold of the synthetic extremely-narrow pulse radar based on the resampling algorithm is characterized by comprising the following steps of:
step one, inputting the number N of test statistics and arranging the false alarm rate into p in the order from large to small1,p2,...,pMThe detector window length is L;
step two, the resampling random sample generator generates N windows with the length of L and the probability density function of f1Of the noise signal xn={x1,x2,...,xL},n=1,2,...,N;
Step three, calculating the weight corresponding to the nth group of noise samples;
Step four, generating N test statistics T according to the judgment rule of the detectorn(x),n=1,2,...,N;
Step five, initializing a quantile generator, setting (2M +3) quantiles, and sequencing the first (2M +3) test statistics in a sequence from small to large to obtain a sequence statistic T(i)I 1, 2., (2M +3), calculated to yield T(i)Corresponding sample weight wiFor the size q of the ith quantile valueiRepresents the number n of accumulated samples corresponding to the ith quantileiSample increment Δ n corresponding to time-division bit points when the algorithm executes sequentiallyiAnd represents the desired number of samples n 'for the ith quantile'iThe following assignment operations are performed:
qi=T(i),i=1,2,...,(2M+3);
n′i=1+2(M+1)Δni;
step six, inputting the jth test statistic Tj(x) Performing iterative update of a threshold, wherein j > (2M + 3);
step seven, outputting q2m+1As false alarm rate pm(M1, 2.. times.m) corresponds to an estimate of the threshold.
2. The resampling algorithm based synthetic extremely narrow pulse radar detection threshold calculation method according to claim 1, wherein the sixth step comprises:
a) will Tj(x) And q isiI 1, 2., (2M +3) are compared and T is determinedj(x) In the section, return toIntermediate variable k, when Tj(x)<q1Or Tj(x)>q2M+3When q is updated1Or q2M+3;
b) Updating niAnd n'j:
ni=ni+wi,i=k,...,2M+3;
n′i=n′i+Δn′i,i=1,...,2M+3;
c) Adjusting the threshold corresponding to the (2M +2) th component site:
d=n′i-ni,i=2,...,2M+2;
dl=ni-1-ni;dr=ni+1-ni;
if (d is not less than 1 and drGreater than 1) or (d is less than or equal to-1 and d isr< -1 >), then order
d′=sign(d);
If q isi-1<q′i<qi+1Let the ith threshold and the number of samples be:
qi=q′i;
ni=n′i;
otherwise
ni=n′i。
3. The resampling algorithm based synthetic extremely narrow pulse radar detection threshold determining method as claimed in claim 2, wherein said step a) comprises:
at Tj(x) In the interval of Tj(x)<q1Then, the intermediate variable k is returned to 1, and q is updated1=Tj(x);
At Tj(x) In the interval q1≤Tj(x)<q2If yes, returning an intermediate variable k to be 1;
at Tj(x) In the interval q2≤Tj(x)<q3If yes, returning an intermediate variable k to be 2;
......;
at Tj(x) In the interval q2M+2≤Tj(x)<q2M+3If yes, returning an intermediate variable k which is 2M + 2;
at Tj(x) In the interval q2M+3<Tj(x) Then, the intermediate variable k is returned to 2M +2, and q is updated2M+3=Tj(x)。
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