Conventional multiple-input and multiple-output
(MIMO) radar is a flexible technique which enjoys the advantages
of phased-array radar without sacrificing its main
advantages. However, due to its range-independent directivity,
MIMO radar cannot mitigate nondesirable range-dependent
interferences. In this paper, we propose a range-dependent
interference suppression approach via frequency diverse array
(FDA) MIMO radar, which offers a beamforming-based solution
to suppress range-dependent interferences and thus yields much
better DOA estimation performance than conventional MIMO
radar. More importantly, the interferences located at the same
angle but different ranges can be effectively suppressed by the
range-dependent beamforming, which cannot be achieved by
conventional MIMO radar. The beamforming performance as
compared to conventional MIMO radar is examined by analyzing
the signal-to-interference-plus-noise ratio (SINR). The Cramér-Rao lower bound (CRLB) is also derived. Numerical results
show that the proposed method can efficiently suppress range-dependent
interferences and identify range-dependent targets. It is particularly useful in suppressing the undesired strong
interferences with equal angle of the desired targets.
1. Introduction
Multiple-input and multiple-output (MIMO) radar has received much attention in recent years. But for conventional colocated MIMO radar, the array manifold caused by time delay only depends on the angle and thus has difficulty in distinguishing the targets and interferences that have the same angle but different ranges by general beamforming techniques [1–3]. Moreover, the localization performance will also be significantly degraded [4, 5] with the targets with the same angle but different ranges. The conventional MIMO radar cannot distinguish range-dependent targets. According to the radar ambiguity function, the range and velocity of a target cannot be simultaneously estimated. Several methods have been suggested to solve these problems. A potential solution is using multiple distributed receivers. But it requires clock synchronization due to separated receivers, which is a technical challenge.
Frequency diverse array (FDA) radar proposed in [6–8] can suppress range-dependent interferences. Different from phased-array radar, a small frequency increment, as compared to the carrier frequency, is applied between FDA elements [9, 10]. This small frequency increment results in a range-angle-dependent beampattern [11–13]. The time and angle periodicity of FDA beampattern was analyzed in [14]. A linear FDA was proposed in [15] for forward-looking radar ground moving target indication. The application of FDA for bistatic radar system was analyzed in [16]. And the imaging of FDA radar was investigated in [17–19]. In [20], we have derived the FDA Cramér-Rao lower bounds (CRLBs) for estimating direction, range, and velocity. Although FDA has drawn much attention in antenna and radar areas, the existing literature concentrates on FDA conceptual system design [21, 22]. Furthermore, most of the FDA MIMO radar literature focuses on beamforming algorithm [23–25], and little work on target localization application and its performance analysis has been reported [26, 27].
In this paper, we design the FDA MIMO radar for range-dependent beamforming and target localization. Our proposed approach exploits jointly the advantages of FDA and MIMO techniques. The advantages of FDA MIMO radar as compared to conventional MIMO radar are investigated. Furthermore, the FDA MIMO radar performance is evaluated by the corresponding transmitting-receiving beampattern, and output signal-to-interference-plus-noise ratio (SINR) is also examined. The contributions of this paper can be summarized as follows. (i) We formulate the data model of FDA MIMO radar. (ii) Range-dependent interferences/targets with the same angle of the targets are suppressed/detected by the FDA MIMO adaptive beamformer. (iii) The CRLB of FDA MIMO radar is derived, along with extensive numerical results. (iv) We derive and verify the resolution probability of FDA MIMO radar localization.
The rest of this paper is organized as follows. In Section 2, we formulate the FDA MIMO radar data model. And we present an FDA MIMO radar adaptive beamforming approach with range-dependent interference suppression in Section 3. In Section 4, the multiple signal classification (MUSIC) algorithm is employed for target localization in angle-range dimension. Simulation results are provided in Section 5. Finally, conclusions are drawn in Section 6.
2. Data Model of FDA MIMO Radar
Consider an FDA MIMO radar equipped with M colocated transmitting elements and N colocated receiving elements. Assume the transmit and receiving arrays are closely located, so that a target located in far field can be seen by both of them at the same spatial angle. Each transmitting element sends out a distinct omnidirectional waveform sm(l), m=1,2,3,…,M and l=1,2,3,…,L. Let s(l) be the vector collecting all these waveforms. The baseband equivalent model, in complex-valued form, of the transmitted signals from the mth transmit element can be expressed as(1)amθ,rsml,where(2)amθ,r=ej∗2πm-1d/λsinθ-m-1Δf/cr+m-12Δf/cdsinθ≈ej∗2πm-1d/λsinθ-Δf/cris the mth entry of the transmit steering vector with Δf being the frequency increment [25] while d is the element space, λ is the carrier wavelength, c denotes the light speed, and θ and r are the target angle and range, respectively. As a comparison, (3) gives the mth entry of the steering vector for a phased array, which is not related to the range variable r:(3)ej2πm-1d/λsinθ.The FDA MIMO radar transmit steering vector depends on both the range and the angle, whereas that of conventional MIMO radar depends only on the angle. Therefore, the interferences with the same angle of the targets cannot be suppressed by conventional MIMO radar but may be resolved by the FDA MIMO radar.
For a position with angle θ and range r, the phase difference between the two signals transmitted by two adjacent elements is(4)ϕ1=2πdλsinθ-Δfcr.Thereby, the transmit steering vector is given by(5)attθ,r=1,ejϕ1,ej2ϕ1,…,ejM-1ϕ1T.After being reflected by the targets or interferences, the signals are received by the colocated receiving array. Taking the first element as a reference, the phase difference of the signals received by two adjacent elements is(6)φ=2πdλsinθ.Similarly, the receiving steering vector is(7)arθ=1,ejφ,ej2φ,…,ejN-1φT,where [·]T denotes the transpose operator. The phase difference ϕ1 of the transmit steering vector becomes(8)ϕ2=2πdλsinθ-Δfc2r,where 2r is caused by reflected range. Therefore, the new transmit steering vector at the receiving array is given by(9)atrθ,r=1,ejϕ2,ej2ϕ2,…,ejM-1ϕ2T.Suppose there is a target located at the position (θ0,r0) along with multiple interferences located at (θi,ri). N×1 receiving complex vector of the receiver observations can be written as(10)xl=δ0τarθ0atrTθ0,r0sl+∑iδiτarθiatrTθi,risl+nl,l=1,2,…,L,where δ0τ stands for the complex amplitude of the target and δi(τ) represents the complex amplitude of the ith interference source and n(l) is N×1 additive zero-mean white Gaussian noise term with covariance matrix σ2I, with σ2 being the noise power. Note that τ is the slow time and l is the fast time. Since sm(l) is orthogonal, the received signals can be processed by a matched filter, which outputs an M×N matrix:(11)Yl=∑l=1LxlsHl∑l=1LslsHl-1=δ0τarθ0atrTθ0,r0+∑iδiτarθiatrTθi,ri+N,where(12)N=∑l=1LnlsHl∑l=1LslsHl-1.[·]-1 and [·]H denote the matrix inverse operator and conjugate transpose operator, respectively, and ∑ denotes summation operator. Furthermore, it is easy to show that N is independent and identically distributed (i.i.d.) Gaussian entries with zero mean and variance σ2. Stacking the columns of Y, we obtain an MN×1 virtual data vector(13)y≜vecY=δ0τaθ0,r0+∑iδiτaθi,ri+n,where vec denotes vectorization operator and n≜vec(N), and(14)aθ,r≜atrθ,r⊗arθdenotes the joint transmit-receiving virtual steering vector, in which ⊗ stands for the Kronecker product. The interference-plus-noise covariance matrix can be expressed as(15)R=∑iαi2aθi,riaHθi,ri+σ2I,where i denotes the index of interferences and αi2=E[δi(τ)δi(τ)∗] is the averaged power.
3. Adaptive Beamforming and SINR Analysis for FDA MIMO Radar
In this section, we consider the adaptive beamforming which can suppress the range-dependent interferences having the same angle but different ranges from that of targets. The performance is examined in terms of the output signal-to-interference-plus-noise ratio (SINR). For discussion convenience, we rewrite the output of matched filter as follows:(16)y≜vecY=δ0τaθ0,r0+∑iδiτaθi,ri+n.To suppress the interferences, the conventional MVDR beamformer for a target located at (θ0,r0) is employed by(17)wMVDR=arg minwwHRws.t.wHaθ0,r0=1.The first term denotes the interference power minimization, and the second term stands for ensuring the target signal without distortion. The weight vector can be solved as(18)wMVDR=R-1aθ0,r0aHθ0,r0Raθ0,r0.However, the MVDR beamformer does not make constraints on the sidelobe. In order to suppress the sidelobes, (17) can be reformulated as(19)w=arg minwwHRws.t.wHaθ0,r0=1wHaθSL,rSL≤ɛ,where (θSL,rSL) is the position of the sidelobe and ɛ is the sidelobe level. Accordingly, the beampattern is given by(20)Pθ,r=aHθ,rwMVDR2.
The SINR can be calculated by(21)SINR=α02wHaθ0,r0aHθ0,r0wwH∑iαi2aθi,riaHθi,ri+Qw,where α02 and αi2 are the target signal and interference signals averaged power, respectively, and the diagonal Q is the noise covariance matrix.
It is well known that inverse of an M×M Hermitian symmetric matrix requires O(M3) operations. For the FDA MIMO radar, since y is an MN×1 vector, computing R-1a(θ0,r0) and aH(θ0,r0)Ra(θ0,r0) requires O(M2N2+M3N3) and O(2M3N3) operations, respectively [28]. Then, computation complexity is O(M2N2+3M3N3). The traditional MIMO radar has the same computation complexity. However, traditional MIMO radar has equal transmit and receiving array spacing, and its computing complexity will be O((M+N)2+3(M+N)3) [29].
4. FDA MIMO Radar Localization Performance and Resolution Probability Analysis
In this section, we analyze the FDA MIMO radar localization performances in terms of CRLB and resolution probability. The FDA MIMO radar localization can estimate not only target angles, but also target ranges. We can regard both target and interferences as sources. In this case, (13) can be reformulated as(22)y≜vecY=∑sδsτaθs,rs+n,where the subscript “s” denotes the number index of targets. Defining A1(θ,r)=aratrT, we can get(23)A1θ,r=1ejϕ2⋯ejM-1ϕ2ejφejϕ2+jφ⋯ejM-1ϕ2+jφej2φejϕ2+j2φ⋯ejM-1ϕ2+j2φ⋮⋮⋯⋮ejN-1φejϕ2+jN-1φ⋯ejM-1ϕ2+jN-1φ.The first column is the receiving steering vector given in (9). Thus, we can estimate the target angle θ through the received signals. Similarly, the range r can also be estimated.
According to (22), the covariance matrix can be obtained by(24)Ry=EyyH=A2θ,rEδsδsHA2Hθ,r,where A2(θ,r)=[a(θ1,r1),a(θ2,r2),…,a(θS,rS)] is the receiving steering matrix for multiple signals with S being the number of targets and δs=[δs(1),δs(2),…,δs(τ)]. For independent target signals and noise, Ry can be reformulated as(25)Ry=A2θ,rΛ000A2θ,rH+αn2I=UA⋯UnΛ+σS2I00σM-S2IUA⋯UnH, where UA and Un are the unitary matrices of signal and noise subspaces, respectively, Λ denotes the target signal power, and I is the unit matrix. The rank of Λ+σS2I is equal to the number of targets. Once the number of signals is obtained, the sizes of UA and Un are known accordingly. According to the MUSIC principle, the targets can be localized by searching the following peaks:(26)Pθ,r=1aHθ,rUnUnHaθ,r.
The eigenvalue decomposition (EVD) of an M×M Hermitian symmetric matrix requires a computation complexity of O(41/3M3) [28]. According to Section 3, the total computation complexity of an FDA MIMO radar is O(51/3M3N3), which is the same as that of a traditional MIMO radar. When the transmit and receiving arrays have the same element spacing, the computation complexity will be O(51/3(M+N)3) [29].
To derive the CRLB, we rewrite (10) as(27)xl=δ0arθ0atrTθ0,r0sl+∑iδiarθiatrTθi,risl+nl=∑sδsarθsatrTθs,rssl+nl=BθΛAθ,rsl+nl, where(28)Bθ=arθ1arθ2⋯arθS,Aθ,r=atrθ1,r1atrθ2,r2⋯atrθS,rS,δ=δ1δ2⋯δS,Λ=diagδ, with diag denoting a diagonal matrix. Note that, for notation convenience, τ has been included in δ. The unknown parameter vector to be estimated is then given by(29)η=θTrTδ-Tδ^TT, where θ=[θ1,θ2,…,θS]T, r=[r1,r2,…,rS]T, δ-=[δ-1,δ-2,…,δ-S]T, and δ^=[δ^1,δ^2,…,δ^S]T are the real part and image part of δ, respectively. We divide η into deterministic and random components,(30)η=βTγTT, where β=θTrTT are the deterministic parameters and γ=[δ-T,δ^T]T are random components. The Fisher information matrix (FIM) with respect to η is(31)Fβi,βj=2Retr∂BθΛATθ,rSH∂βiQ-1∂BθΛATθ,rS∂βj, where Q=σ2I is the noise covariance matrix, Re denotes the real part, and tr(·) stands for the trace of a matrix. Equation (31) can be written as(32)Fβi,βj=2σ2Retr∂BθΛATθ,r∂βjSSH∂BθΛATθ,rSH∂βi=2Lσ2Retr∂BθΛATθ,r∂βi∂BθΛATθ,rSH∂βj, where the facts that trAB=tr(BA) and SSH/L=I are used. Due to the fact that tr(AB)=vec(AT)Tvec(B)T, we can get(33)Fβi,βj=2Lσ2Revec∂BθΛATθ,rH∂βiHvec∂BθΛATθ,r∂βj. We take a derivative with respect to θi(34)∂BθΛATθ,r∂θi=B˙θeieiTΛATθ,r+BθeieiTΛA˙Tθ,r=∂arθi∂θiδiatrθi,riT+arθiδi∂atrθi,ri∂θi, where ei represents the ith column of the unit matrix and B˙ denotes the derivation of B (similar for A˙). We take also a derivative with respect to ri,(35)∂BθΛATθ,r∂ri=BθeieiTΛA˙Tθ,r=arθiδi∂atrθi,ri∂ri. We then have(36)vec∂BθΛATθ,r∂θi=∂arθi∂θi⊗atrθi,ri+arθi⊗∂atrθi,ri∂θiδi=dθθi,riδivec∂BθΛATθ,r∂ri=arθi⊗∂atrθi,ri∂riδi=drθi,riδi, where the fact that vec(AVBT)=B⊗Avec(V) is utilized. Define(37)Δ≜dθθ1,r1·δ1,…,dθθS,rS·δSdrθ1,r1·δ1,…,drθS,rS·δS. The FIM with respect to β part can be calculated by(38)Fβ,β=2Lσ2ReΔH·Δ. Similarly, we have(39)vec∂BθΛATθ,r∂δ-i=arθi⊗atrθi,ri,vec∂BθΛATθ,r∂δ^i=jarθi⊗atrθi,ri, where δ-i and δ^i are the real and imaginary part of reflection coefficient δi, respectively. Defining vi=ar(θi)⊗atr(θi,ri) and V=[v1,v2,…,vS], we can get [30](40)Fβ,δ-=2Lσ2ReΔH·V,Fβ,δ^=-2Lσ2ImΔH·V,Fδ-,δ-=Fδ^,δ^=2Lσ2ReVH·V. Therefore, the FIM of FDA MIMO radar is derived as(41)F=Fβ,βFβ,δ-Fβ,δ^Fβ,δ-Fδ-,δ-Fδ-,δ^Fδ^,βFα^,δ-Fδ^,δ^=2Lσ2ReΔHΔReΔHV-ImΔHVReΔHVReVHV-ImVHVImΔHVImVHVReVHV=2Lσ2ReΔHΔΔHV-jΔHVΔHVVHV-jVHVjΔHVjVHVVHV=2Lσ2ReΔHVHjVHΔV-jV.Finally, the CRLBs with respect to θi and ri are the two diagonal elements of the inverse of the FIM: (42a)CRLBθi=F-1i,i(42b)CRLBri=F-1S+i,S+i, where F-1 is the inverse of F and [·]i,j is the element at the ith row and jth column of the matrix. Since matrices Δ and V depend on both range and Δf, the CRLBs are influenced by Δf.
Furthermore, we use the resolution probability defined as follows to compare the localization performance. Two targets can be resolved only when the following relation is achieved: (43a)θ^1-θ1≤θ1-θ22(43b)θ^2-θ2≤θ1-θ22,where θ1 and θ2 are the true directions.
5. Simulation Results
Suppose the following simulation parameters: M=N=8, f0=10 GHz, d=λ/2, c=3×108 m/s, Δf=30 KHz, L=256, SINR=10 dB, and τ=256. The additive noise is modeled as complex Gaussian zero-mean spatially and temporally white random sequences.
Example 1 (adaptive beamforming and performance analysis).
In the first example, one target of interest and multiple interferences are located at (θs,rs) = (10°, 10 km) and (θj,rj) = (10°, 6.5~9 km), respectively.
Figure 1(a) gives the adaptive beampattern of conventional MIMO radar. Obviously, it cannot suppress the interferences having the same angle as the targets shown in Figure 2. In this case, the interferences will degrade the SINR performance. In contrast, the beampattern mainlobe of FDA MIMO radar can be steered to suppress range-dependent interferences, as shown in Figure 1(b) and Figure 2. The FDA MIMO radar beampattern has zero nullings at the interference locations and, thus, the sidelobes are significantly suppressed.
Comparative transmit beampattern: (a) conventional MIMO radar and (b) FDA MIMO radar.
Comparative transmit beampattern in range profile θ=10°.
We also examined the adaptive beamformer output SINR versus input SINR. In the first case, we assume that the target and interference have the same angle but different ranges. Figure 3(a) shows the comparative beamforming performance. It is noticed that FDA MIMO radar has a much higher output SINR than conventional MIMO radar. In the second case, the target and interference are at angles θs=10° and θi=-10°, respectively. It is seen from Figure 3(b) that the output SINR of FDA MIMO radar is equivalent to that of phased MIMO radar. Consequently, FDA MIMO radar outperforms conventional MIMO radar in interference suppression.
Output SINR comparisons: (a) target and interferences are at the same angle but different ranges; (b) target and interferences are at different angles.
Example 2 (localization and performance analysis).
Consider four targets with locations (-20°, 8 km), (20°, 8 km), (-20°, 10 km), and (20°, 10 km) and SNR=10 dB. Figure 4 compares the localization results. Since conventional MIMO radar can only estimate target angles, there are only two curves for conventional MIMO radar. Consequently, conventional MIMO radar fails to resolve the four targets completely.
Power spectra: (a) FDA MIMO radar and (b) conventional MIMO radar.
In contrast, the four targets can be easily identified by the FDA MIMO radar, as shown in Figure 4(a). Furthermore, to clearly compare the performance, the amplitude spectrum profile cut at angle 20° is given in Figure 5. It shows that the target ranges are correctly estimated by the FDA MIMO radar.
Power spectra profile for FDA MIMO radar in range dimension for angle 20°.
Figure 6 compares the CRLB as a function of SNR. The FDA MIMO radar steering vector depends on Δf. Figure 6(a) gives the CRLB for angle θ estimation at different Δf. It is seen that CRLB for θ holds as Δf increases, whereas CRLB for range r decreases as Δf increases, as shown in Figure 6(b).
Comparative CRLB results for FDA MIMO radar with different Δf: (a) angle estimation and (b) range estimation.
Figures 7(a) and 7(b) show the mean square error (MSE) [31] and CRLB on angle and range estimations versus SNR, respectively. Note that the MSEs are computed based on 100 independent Monte Carlo simulation runs. In Figure 7(a), the conventional MIMO radar has two target signals having the same angle whereas the FDA MIMO radar MSE is obtained by considering only one target. Therefore, the previous result outperforms that of the FDA MIMO radar in angle estimation. Nevertheless, it can be seen that the proposed approach gives a satisfactory estimation performance.
Comparison of CRLB and MSE for FDA MIMO radar: (a) angle estimation and (b) range estimation.
Finally, the resolution probability performances are compared in Figure 8(a). It can be seen that FDA MIMO radar still outperforms conventional MIMO radar. Figure 8(b) shows the resolution probability versus Δf. Since Δfr=c0, if Δf increases, the range r will decrease. Hence, the resolution probability will decrease along with the decrease of Δf for FDA MIMO radar.
Resolution probability: (a) FDA MIMO radar and conventional MIMO radar and (b) different Δf for FDA MIMO radar.
6. Conclusion
In this paper, we proposed an FDA MIMO adaptive beamforming and localization scheme for range-dependent targets and interferences with the same angle but different ranges. The FDA MIMO radar provides a promising range-dependent beampattern, which is particularly valuable for suppressing range-dependent interferences. The FDA MIMO radar has higher output SINR than the conventional MIMO radar. Besides, the ranges and angles of targets can be solely estimated with MUSIC-based algorithm. This conclusion is also validated by the CRLB and MSE for FDA MIMO radar which are also analyzed to examine the estimation performance comparisons.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
Acknowledgment
This work was supported in part by the Program for New Century Excellent.
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