Academic Editor:Ana Alejos

Key Laboratory of Radar Imaging and Microwave Photonics, Ministry of Education, College of Electronic and Information Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 211100, China

Received 1 July 2016; Accepted 5 October 2016

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

1. Introduction

With the development of aircraft stealth technology, there is a growing need for radar to detect weak maneuvering targets in a noisy background. It is a known fact that pulse integration especially coherent integration can improve the signal-to-noise ratio (SNR) and ultimately improve the detection performance [1].

Concentrating on coherent integration, a lot of work has been carried out. The most commonly used method is moving target detection (MTD) [2], which achieves integration by using Doppler filter bank. However, MTD method can only deal with the target with uniform velocity and will become invalid if the range migration (RM) exceeds one range bin during the integration time [3]. It is of vital importance to eliminate RM since the high-speed target can easily exceed several range units even in a short time. To deal with RM, keystone transform (KT) [4, 5] was performed by rescaling the time axis for each frequency and is often performed before MTD. In actual detecting environment, for example, the velocity, acceleration, and jerk will result in first-order RM, second-order RM, and third-order RM, respectively. Unfortunately, conventional KT can only correct the first-order RM. Thus [6-8] studied second-order KT to correct the second-order RM and Kong et al. [9] proposed a coherent integration method via generalized KT and generalized dechirp process (GKTGDP) for maneuvering targets with arbitrary high-order RM. It is worth paying attention to that KT could be invalid without ambiguity correction if Doppler ambiguity happens. Algorithms for Doppler ambiguity correction are hardly independent of Doppler ambiguous integers searching; thus, the computational burden will greatly increase.

In recent years, a new method called Radon-Fourier transform (RFT) [10-12] has been proposed to realize long-time coherent integration via jointly searching along range and velocity directions. The detection performance of the high-speed and weak targets with constant velocity can be significantly improved by RFT if one of the searching pairs matches well with actual values. In consideration of maneuvering targets, generalized RFT (GRFT) [10, 13] was also defined for targets with arbitrary parameterized motion. Based on the idea of GRFT, a lot of work has been done recently [14-17]. Actually, the GRFT suffers from heavy computational burden and is impractical without fast implementations because of the multidimensional ergodic search. Fortunately, the realization of GRFT can be converted into an optimization problem in parameter space. Thus, intelligent optimization algorithms can be utilized to eliminate a large number of unnecessary searching paths. Another drawback of GRFT is the BSSL problem [10, 11] derived from discrete pulse sampling, finite range resolution, and limited integration time, which will lead to intelligent optimization algorithms converging to local optimum easily. Following consideration of the above issues, Qian et al. [18] have proposed BSSL learning-based particle swarm optimization (BPSO) to fast implement GRFT. By using the relation of BSSL and the main lobe, the local convergence can be avoided and the convergence speed can be accelerated simultaneously.

Although BPSO-based GRFT is efficient, it suffers from apparent detection performance loss compared with GRFT. To improve the detection performance, this paper proposes the BSSL learning-based modified wind-driven optimization (BMWDO). The wind-driven optimization (WDO) [19, 20] is a stochastic nature inspired, population based iterative heuristic global optimization method based on atmospheric motion. Compared with the traditional PSO, WDO employs additional terms in the velocity update equation, providing robustness and extra degrees of freedom for fine-tuning. However, it could be difficult in choosing optimum WDO coefficients for GRFT because the location of the optimum point depends on the motion parameters which have large dynamic ranges. In order to deal with the difficulty in choosing coefficients and further improve the global optimization ability of WDO in a noisy environment, we propose a modified WDO method which adjusts the control coefficients in WDO with random distributions, namely, MWDO. Detailed numerical experiments demonstrate that the proposed BMWDO method can improve the detection performance with a similar running time compared with BPSO.

2. Signal Model and GRFT

2.1. Signal Model

Suppose that radar transmits linear frequency modulated (LFM) signal, that is, [figure omitted; refer to PDF] where [figure omitted; refer to PDF] _Tp is the pulse width, γ is the frequency modulated rate, and _fc is the carrier frequency. Let _tm =m_Tr (m=0,2,...,M-1) denote the slow time, where _Tr denotes the pulse repetition time, M is the number of pulses, and t^=t-m_Tr is the fast time.

The received radar echo after carrier frequency demodulation can be denoted as [figure omitted; refer to PDF] where R(_tm ) is the distance between radar and target at the radar line-of-sight and _A0 is the amplitude of the echo. The time delay of the echo is τ(_tm )=2R(_tm )/c, where c is the speed of light. After pulse compression via using the baseband transmitted signal as the reference signal, that is, [figure omitted; refer to PDF] the received signal in the time domain can be expressed as [figure omitted; refer to PDF] In the above equation, _A1 is the amplitude after pulse compression and B denotes the system bandwidth. The range between radar and target in radial direction varies with the slow time _tm and can usually be expressed as a polynomial function of _tm , which can be expanded into Taylor series [16], that is, [figure omitted; refer to PDF] where P-1 is the motion order, _Tn is the coherent integration time, and ^αP =(_α0 ,_α1 ,...,_αP-1 ) is the motion parameter vector. It is obvious that the peak location of the sinc function varies with _tm and the changes will exceed the range resolution _ρr =c/2B easily if the integration time is long or the motion parameters are not very small, which means that the across range unit (ARU) effect will happen. The Doppler frequency can be calculated as [figure omitted; refer to PDF] where λ=c/_fc is the wavelength, _f0 =2_α1 /λ is the central frequency of Doppler, and the parameter _α1 is the target's velocity. If the target has acceleration or higher motion parameters, the Doppler frequency will be time-varying. If the changes of _fd exceed the Doppler resolution _ρd =1/_Tn , the Doppler frequency migration (DFM) will come across. In order to coherently accumulate the target's energy, we need to correct both the ARU and the DFM.

2.2. Definition and Analysis of GRFT

GRFT is a coherent integration algorithm via jointly searching in multidimensional parameter space. By using GRFT, the trace of the target can be extracted and the DFM can be compensated at the same time. The definition of GRFT in [10] is given as follows.

Definition 1.

Suppose a 2D complex function f(_tm ,t^)∈C is defined in the (_tm ,t^) plane and a parameterized P-dimensional function t^=η(_tm ;^{α^P} ) is used for searching a certain time-varied curve in the plane, where ^{α^P} =(_α^0 ,_α^1 ,...,_α^P-1 ). Then GRFT can be defined as [figure omitted; refer to PDF] where [straight epsilon] is a known constant with respect to η(_tm ;^{α^P} ).

Let f(_tm ,t^)=_SPC (_tm ,t^); then (8) can be rewritten as [figure omitted; refer to PDF] where τ^(_tm )=(2/c)^∑p=0P-1 (1/p!)_α^p^tmp . Suppose that P=2; then GRFT degenerates into RFT which deals with the case of uniform velocity. From (9), we can easily know that when the searching values of motion parameters (_α^0 ,_α^1 ,...,_α^P-1 ) are exactly the target's real motion values (_α0 ,_α1 ,...,_αP-1 ), the coherent integration could be achieved and the peak would be formed in the parameter space, that is, [figure omitted; refer to PDF] Then the target can be detected and the motion parameters can be easily obtained by the location of the peak in the parameter space. However, because of limited integration time, discrete pulse sampling, and finite range resolution, the BSSL [10, 11] will also be formed in parameter space, which influences target detection performance. The causes of BSSL and the relations between BSSL and the main lobe are discussed as follows.

Equation (9) can be rewritten as [figure omitted; refer to PDF] where [figure omitted; refer to PDF] When _α^p =_αp (p=2,...,P-1) and _α^1 -_α1 =q_vb , where _vb =c/2_fcTr is the blind speed and q is the blind speed integer, we have exp(Δ[varphi](_tm ))=1 in (11). It is obvious that the phase can be compensated even though q≠0, which results in the BSSL phenomenon. Slice of BSSL can be denoted as [figure omitted; refer to PDF] The blind speed integer q∈((_α^1min -_α1 )/_vb ,(_α^1max -_α1 )/_vb ), where (_α^1min ,_α^1max ) is the searching range of velocity.

By analyzing (11), (12), and (13), we can see that the properties of BSSL are irrelevant to _α^p (p=2,...,P-1). Thus, the case of constant velocity is taken as an example to analyze the relations between BSSL and the main lobe. The sketch map of BSSL is illustrated in Figure 1. Suppose that the target's velocity is _v1 , the initial range is _R0 , and the one-time blind speed is _v2 =_v1 +_vb . The shadow region is formed so that the searching lines with one-time blind speed intersect the range-walk line in the integration time (-_Tn /2,_Tn /2). The searching range of the shadow region is (_R0 -_vbTn /2,_R0 +_vbTn /2); thus the length of the supporting area is [figure omitted; refer to PDF] Because of the finite range resolution, the overlapped pulse number in the intersection of the range-walk line and the searching line is [figure omitted; refer to PDF] The n pulses are also coherently integrated. Thus, the primary lobe to side lobe ratio (PSLR) can be denoted as [figure omitted; refer to PDF] In general, in the case that the blind speed integer q≠1, [figure omitted; refer to PDF] With the increase of (q), the supporting area of BSSL becomes longer and the amplitude of the side lobe decreases.

Figure 1: Sketch map of the BSSL phenomenon.

[figure omitted; refer to PDF]

3. Fast Implementation of GRFT via BMWDO

3.1. Modified Wind-Driven Optimization

The wind-driven optimization (WDO) algorithm [19, 20] is inspired from the Earth's atmosphere where wind blows in an attempt to equalize imbalances in air pressure. The model of WDO is based on the definition of trajectories of small air parcels within the Earth atmosphere according to Newton's second law of motion.

WDO is very similar to PSO [21] in that these air parcels are also described by positions and velocities which refer to candidate solutions and the amount of position displacement, respectively. Particles in WDO refer to small air parcels that are assumed dimensionless and weightless for simplification. In WDO, a population of air parcels is distributed throughout N-dimensional problem space, and the velocity of air parcel is updated in each iteration process based on the equation which is derived from Newton's second law of motion and the ideal gas laws. It is given by [figure omitted; refer to PDF] where i represents the rankings of the air parcels since all the parcels are ranked according to their pressure. The "pressure" represents the value of the objective function in different problems. If we attempted to find the maximum (minimum) value of the objective function, parcels should be ranked in descending (ascending) order. Equation (18) demonstrates that the updated velocity _Unew for the next iteration process is associated with the current velocity _Ucur , the current position _Xcur , the optimal position _Xopt with the highest pressure value that has been found until the current iteration, and the current velocity ^{Ucurother dim} which is randomly chosen from other dimensions. Coefficients α, g, R, T, and C are related to the friction coefficient, gravity, universal gas constant, temperature, and the influence of the Coriolis force in the physical model. The position of air parcel can be updated by [figure omitted; refer to PDF] where Δt=1 is assumed for simplicity.

Before performing WDO, the four coefficients α, g, RT, and C should be chosen firstly. As illustrated in [19], the optimum performance of WDO can be achieved by selecting proper values for the four coefficients, but the optimum values of the WDO coefficients may vary from problem to problem. In GRFT, the optimum location of parcels is related to the target's motion state. In each detection process, the motion states of targets are difficult to predict and the motion parameters may have large dynamic ranges, so it is scarcely possible to find a single set of coefficients that will work efficiently in each case. Considering the problem, we propose the modified WDO (MWDO) to tune α, g, RT, and C in each iteration by random distributions. By applying MWDO, we can avoid a large number of trials to select the optimum coefficients. When choosing the appropriate random distribution, the global optimization ability of WDO in a noisy environment is primarily considered. The values of coefficients are given by [figure omitted; refer to PDF] where the random number rand_U is uniformly distributed between 0 and 1 and the random number rand_L is subject to Levy distribution. The Levy distribution [22, 23] is a continuous probability distribution for a nonnegative random variable and its probability density function over the domain x≥μ is [figure omitted; refer to PDF] where μ is the location parameter and γ is the scale parameter. In (20), (21), and (22), μ=0 and γ=0.001 are selected.

Through analyzing the characteristics of Levy distribution, we can find that the random number rand_L has a great probability to be very small values and will occasionally be big values. It means that, in most cases, other parcels move slowly to the current optimal parcel. In other words, the position updating step length is small but occasionally big. We know that the current optimal position is usually the noise peak position especially when the SNR is very low, so if other parcels move towards the current optimal one with a large step length, the global optimal solution will be missed with a great probability and the diversity of parcels will lose rapidly. The small step length of parcels helps to maintain the population diversity and reduce the probability of flying past the optimal solution. The occasional large step length avoids the parcels converging too slowly and helps parcels jump to other searching areas without being trapped in a small local area, which is useful in improving the global searching ability. Therefore, the Levy distribution is appropriate to tune the coefficients of WDO. By applying MWDO, the optimization ability of WDO in a noisy environment can be enhanced and, at the same time, the difficulty in choosing proper coefficients in WDO can be overcome.

3.2. BSSL Learning-Based MWDO in GRFT

When applying MWDO in GRFT, a great number of unnecessary searching paths can be eliminated, which means the GRFT can be calculated efficiently. However, big values of BSSL in GRFT may cause local convergence to side lobes. To settle this matter, we propose a BSSL learning-based MWDO to find the main lobe by using the relations between side lobes and the main lobe. The detailed description of the proposed method is given as follows and the whole target detection procedure based on BMWDO is shown in Figure 2.

Figure 2: Flow chart of the target detection method via BMWDO.

[figure omitted; refer to PDF]

Step 1 (initialization).

Step 1.1 . Specify the basic conditions in MWDO, including the population size S, the maximum number of iterations _kmax , the dimension of the searching space P which is related to the motion order, the searching range of each parameter, and the restrictions on velocities of air parcels. The location and velocity of each parcel can be denoted as X=(_x1 ,_x2 ,...,_xP ) and U=(_u1 ,_u2 ,...,_uP ), where _x1 ,_x2 ,...,_xP represents the searching motion parameter _α^0 ,_α^1 ,...,_α^P-1 , respectively.

Step 1.2 . Initialize air parcels' locations by randomly distributing them in the searching space and initialize air parcels' velocities to 0.

Step 1.3 . Sort these parcels based on their pressure values. In GRFT, pressure value of parcel refers to the absolute value of GRFT: (G(X)). The first parcel is the one which has the biggest pressure value and its location can be denoted as _Xopt (0).

Step 2.

Generate the values of coefficients of MWDO via (20), (21), (22), and (23). Then update the velocities and locations of air parcels based on (18) and (19), respectively. Sort these updated air parcels based on their pressure values and find the current optimal air parcel _Xopt (k).

Step 3.

Further update _Xopt (k) by the relations between BSSL and the main lobe to avoid local convergence to BSSL: [figure omitted; refer to PDF] where _Xopt (k;q)=(_α^0 ,_α^1 +q_vb ,_α^2 ,...,_α^P-1 ). As analyzed in Section 2, the amplitude of BSSL is always smaller than that of the target's main lobe; thus (25) is reasonable.

Step 4.

Repeat Step 2 to Step 3 until one of the following two conditions is met:

(1) (G(_Xopt (k)))>γ and k<=_kmax .

(2) (G(_Xopt (k)))<=γ and k>_kmax .

The parameter γ is the detection threshold calculated from the preset false alarm probability.

It should be pointed out that when condition (1) is met, the target is detected and when condition (2) is met, it means that there is no target.

4. Numerical Results

In this section, several numerical experiments are provided to demonstrate the effectiveness of the proposed fast implementation method of GRFT. The BSSL phenomenon is firstly verified and then BMWDO and BPSO are compared in convergence performance. The detection performances of the two fast implementation methods as well as the traditional GRFT, RFT, and moving target detection (MTD) are compared. The running time of the traditional GRFT, the BPSO-based GRFT, and the BMWDO-based GRFT is also provided.

4.1. BSSL Phenomenon

In this part, we suppose that the radar pulse repetition interval _Tr =0.01 s, the bandwidth B=15 MHz, the carrier frequency _fc =150 MHz, and the sample frequency _fs =2B. The blind speed _vb can be calculated as 100 m/s. Suppose that the actual velocity is 300 m/s and the searching range of velocity is [1 m/s, 680 m/s]. The range and velocity slice of GRFT is shown in Figure 3.

Figure 3: Range and velocity slice of GRFT.

[figure omitted; refer to PDF]

From Figure 3 we can intuitively see that, with the increase of (q), the supporting area of BSSL becomes longer and the amplitude of the side lobe decreases, which corresponds to the conclusion drawn from (17). Because the amplitude of BSSL is always lower than that of the main lobe, it is reasonable to employ (25) to help parcels jump out of local convergence to BSSL.

4.2. Convergence Performance

In the following simulations, the radar parameters listed in Table 1 are adopted. The population size S=150 and the maximum number of iterations _kmax =3000 are specified for BPSO and BMWDO. Suppose that the motion parameter vector is α=(62.5 km,160 m/s,5 m/^s2 ,2 m/^s3 ), and the searching ranges of the radial range, velocity, acceleration, and jerk can be given as (60 km,63 km), (0 m/s,300 m/s), (-30 m/^s2 ,30 m/^s2 ), and (-20 m/^s3 ,20 m/^s3 ), respectively. Basic coefficients of PSO are chosen according to [24]. Figure 4 shows the mean results of 20 runs of BPSO and BMWDO. The SNR of the raw data is set to be -10 dB and -28 dB, and convergence graphs under the two cases are shown in Figures 4(a) and 4(b), respectively.

Table 1: Simulation parameters of radar.

Figure 4: Average convergence graphs of BPSO and BMWDO with 20 runs under different SNR (before pulse compression). (a) SNR = -10 dB. (b) SNR = -28 dB.

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

Figure 4(a) demonstrates that when SNR is relatively high, both BPSO and BMWDO can converge to the optimal value, which means that the BSSL learning-based method can avoid local convergence to side lobes effectively. We can also discover that BPSO converges faster than BMWDO. From Figure 4(b), it can be seen that, under low SNR, neither BMWDO nor BPSO can converge to the optimal value for each run. This is because when SNR becomes too low, the target is nearly undetectable even after coherent integration and the intelligent optimization algorithms will converge to noise peaks easily. It is worth paying attention to that the mean pressure values of 20 runs of BMWDO are closer to the optimal value in Figure 4(b). This result indicates that BMWDO has greater chance to jump out of the local convergence to noise peaks compared with BPSO; in other words, BMWDO has better antinoise performance although it has slower convergence speed.

4.3. Detection Performance

The detection performances of traditional GRFT, BPSO-based GRFT, BMWDO-based GRFT, RFT, and MTD are investigated via Monte Carlo trials. The false alarm probability is set as _Pfa =1^0-6 . Figure 5 shows the detection probabilities of the five detectors with different motion orders. It should be noted that when the motion order equals one, the traditional GRFT degenerates to RFT. It should be pointed out that P is the dimension of searching space while P-1 is the motion order.

Figure 5: Detection performances of five different detectors with different motion orders. (a) Motion order is 1 (P=2). (b) Motion order is 2 (P=3). (c) Motion order is 3 (P=4).

(a) [figure omitted; refer to PDF]

(b) [figure omitted; refer to PDF]

(c) [figure omitted; refer to PDF]

Figure 5 demonstrates that the detection performances of the BMWDO-based GRFT are always better than that of the BPSO-based GRFT under different SNR values or different motion orders. Especially when the motion order equals 1, the detection performance of BMWDO-based GRFT nearly reaches the ideal performance of GRFT. Making comparisons between Figures 5(a), 5(b), and 5(c), we can notice that, with the increase of motion orders, the detection performance of BMWDO-based GRFT decreases. The reason is that when motion order increases, the dimension of the searching space also increases, and the difficulty in finding the optimal solution increases too.

It is not difficult to discover that the decline of the detection probability is not obvious when motion order changes from 2 to 3. This is because the high-order motion parameters have much lower influence on ARU and DFM compared with low-order parameters. When applying BMWDO or BPSO, the low-order motion parameters are dominant in deciding the movement trend of air parcels. Thus, based on the radar parameters adopted in this paper, it is possible to neglect the higher motion parameters and set P=4 for BMWDO in the case that the motion order is greater than or equal to 3. Suppose that the target might have higher motion parameters, such as _α4 =20 m/^s4 , _α5 =20 m/^s5 , and _α6 =20 m/^s6 . With P=4 preset in BMWDO, the detection probabilities of BMWDO-based GRFT with motion orders no less than 3 under different SNR are shown in Figure 6. Due to the randomness of BMWDO and the statistical error, the detection probabilities fluctuate with motion orders, but we can conclude that there is no apparent detection performance loss when choosing P=4 for BMWDO in the case that P>4.

Figure 6: Detection probabilities of BMWDO-based GRFT with motion orders no less than 3. P=4 is preset when calculating BMWDO.

[figure omitted; refer to PDF]

4.4. Computational Cost

In this simulation, the computational costs of the traditional GRFT, the BPSO-based GRFT, and the BMWDO-based GRFT are investigated. The searching ranges of parameters in the traditional GRFT are the same as that in BMWDO and the searching interval of each parameter can be determined according to [14]. Denote the number of range cells, pulse numbers, and motion parameter _αp (p=1,2,3,...,P-1) by _N0 , M, and _Np , respectively. Then the computational complexity is O(^∏p=1P-1_N0 M_Np ) for the traditional GRFT. In this subsection, BPSO and BMWDO are terminated when the number of iterations reaches _kmax . In fact, when condition (1) in Step 4 is met, the two algorithms can be terminated earlier. The running time of BPSO-based GRFT and BMWDO-based GRFT can be experimented accurately. But, for the traditional ergodic-search GRFT, it is difficult to experiment its running time accurately because it is too time consuming. By analyzing, we found that the computational complexity of the traditional GRFT mainly comes from the nested loop; thus, we can calculate the running time of the traditional GRFT by multiplying the loop times with the time required for a loop. The running time of the three algorithms is shown in Figure 7. It is worth noting that when GRFT is applied in engineering, the parallel computing will be used, and the running time of traditional GRFT will not be so horrible but still will be much longer than that of the parallel computed fast implementation methods.

Figure 7: Computational cost of GRFT, BPSO-based GRFT, and the proposed BMWDO-based GRFT.

[figure omitted; refer to PDF]

Figure 7 shows that the computational complexity of BPSO-based GRFT and BMWDO-based GRFT is far less than that of the ergodic-search GRFT. The running time of BMWDO is slightly longer than that of BPSO, which is acceptable. With the increase of motion order, the running time of the traditional GRFT grows nearly exponentially while the running time of BPSO and BMWDO stays stable. Therefore, efficiency and physical realizability of the proposed BMWDO-based GRFT can be validated.

5. Conclusions

In this paper, we propose a fast implementation method for GRFT to reduce the computational burden, namely, BMWDO. By applying BMWDO, a large number of unnecessary searching paths can be eliminated and the local convergence to BSSL can be avoided. Several numerical experiments are provided to analyze the performance of BMWDO in detail, including the convergence performance, the detection performance, and the computational burden. Compared with the traditional ergodic-search GRFT, the proposed method can realize the weak maneuvering target detection in a much more efficient way. Compared with BPSO, the BMWDO has better antinoise performance, which indicates that BMWDO has greater chance to converge to the target's main lobe in a relatively low SNR. The simulation results show that BMWDO has better detection performance and slightly longer running time compared with BPSO, which verify the effectiveness of the proposed method. At last, we should notice that although the BMWDO obviously improves the detection performance compared with BPSO, it still suffers from detection performance loss compared with the traditional GRFT. The reason is that the BMWDO is a stochastic optimization method and it cannot jump out of the convergence to noise peaks each time. Thus, our future work may further study the WDO method and combine it with other algorithms to obtain stronger antinoise performance.

Acknowledgments

The work was supported by the National Natural Science Foundation of China (Grant no. 61201366), the Fundamental Research Funds for the Central Universities (Grant no. NS2016040), the Fundamental Research Funds for the Central Universities (Grant no. NJ20150020), and the Priority Academic Program Development of Jiangsu Higher Education Institutions.