A Low-Complexity Three-Stage Estimator for Low-Rank mmWave Channels

2021 ◽  
pp. 1-1
Author(s):  
Khawaja Fahad Masood ◽  
Rui Hu ◽  
Jun Tong ◽  
Jiangtao Xi ◽  
Qinghua Guo ◽  
...  
Keyword(s):  
Low Complexity ◽  
Low Rank

scholarly journals Channel Covariance Matrix Estimation via Dimension Reduction for Hybrid MIMO MmWave Communication Systems

Sensors ◽  
2019 ◽  
Vol 19 (15) ◽  
pp. 3368
Author(s):  
Rui Hu ◽  
Jun Tong ◽  
Jiangtao Xi ◽  
Qinghua Guo ◽  
Yanguang Yu
Keyword(s):  
Covariance Matrix ◽  
Communication Systems ◽  
Low Complexity ◽  
Low Rank ◽  
Covariance Matrix Estimation ◽  
Hardware Complexity ◽  
Matrix Estimation ◽  
Planar Arrays ◽  
Rank Matrix ◽  
Low Rank Matrix

Hybrid massive MIMO structures with lower hardware complexity and power consumption have been considered as potential candidates for millimeter wave (mmWave) communications. Channel covariance information can be used for designing transmitter precoders, receiver combiners, channel estimators, etc. However, hybrid structures allow only a lower-dimensional signal to be observed, which adds difficulties for channel covariance matrix estimation. In this paper, we formulate the channel covariance estimation as a structured low-rank matrix sensing problem via Kronecker product expansion and use a low-complexity algorithm to solve this problem. Numerical results with uniform linear arrays (ULA) and uniform squared planar arrays (USPA) are provided to demonstrate the effectiveness of our proposed method.

scholarly journals A generalized Fourier transform by means of change of variables within multilinear approximation

2021 ◽  
Vol 8 (1) ◽  
Author(s):  
Mathilde Chevreuil ◽  
Myriam Slama
Keyword(s):  
Learning Algorithm ◽  
Statistical Error ◽  
Reynolds Numbers ◽  
Low Complexity ◽  
Low Rank ◽  
Trigonometric Polynomials ◽  
Change Of Variables ◽  
Functional Representation ◽  
Random Samples ◽  
Selection Of

AbstractThe paper deals with approximations of periodic functions that play a significant role in harmonic analysis. The approach revisits the trigonometric polynomials, seen as combinations of functions, and proposes to extend the class of models of the combined functions to a wider class of functions. The key here is to use structured functions, that have low complexity, with suitable functional representation and adapted parametrizations for the approximation. Such representation enables to approximate multivariate functions with few eventually random samples. The new parametrization is determined automatically with a greedy procedure, and a low rank format is used for the approximation associated with each new parametrization. A supervised learning algorithm is used for the approximation of a function of multiple random variables in tree-based tensor format, here the particular Tensor Train format. Adaptive strategies using statistical error estimates are proposed for the selection of the underlying tensor bases and the ranks for the Tensor-Train format. The method is applied for the estimation of the wall pressure for a flow over a cylinder for a range of low to medium Reynolds numbers for which we observe two flow regimes: a laminar flow with periodic vortex shedding and a laminar boundary layer with a turbulent wake (sub-critic regime). The automatic re-parametrization enables here to take into account the specific periodic feature of the pressure.

scholarly journals Implementation and Performance Analysis of Low Complex Beamforming Algorithms

2019 ◽  
Vol 8 (3) ◽  
pp. 1309-1314
Keyword(s):  
Covariance Matrix ◽  
Input Data ◽  
Krylov Subspace ◽  
Sensor Arrays ◽  
Cost Effective ◽  
Low Complexity ◽  
Adaptive Beamforming ◽  
Low Rank ◽  
Steering Vector ◽  
Interference Noise

The work comprises of low complexity and cost effective technique referred as RAB (Robust Adaptive Beamforming) with the use of two algorithms i.e. LOSCME (Low complexity shrinkage based mismatch estimation) and OKSPME (Orthogonal krylov subspace projection mismatch estimation). The LOSCME is used to estimate the steering vector based on the correlation of the observed input data and beamformer output. This algorithm also uses OAS (oracle approximating shrinkage) in order to estimate the input data covariance matrix and INC (interference noise covariance) matrix that only requires a prior knowledge of angular sector in which the actual steering vector is located. It is not cost effective and need not to know any extra information that is related to interferers which keeps away from finding the direction of all interferers. Simulation result of LOCSME technique shows very close to optimum. The OKSPME algorithm is based on cross-correlation estimation between the observed input data array and output of the beamformer. In this technique the steering vector mismatch is estimated by considering the larger dimension linear equation and FOM (full orthogonalization method) is used to decrease the dimensional subspace. In addition to this, adaptive algorithm is implemented, which is based on the SG (stochastic gradient) & CG (conjugate gradient) searches used to update the beamforming weights, leads to low complexity of the system and avoid any costly matrix inversion. Major advantage of this mismatch estimation with low rank proposed algorithm is cost efficient when using with number of sensor arrays. The result of OKSPME technique shows excellent performance in terms of output SINR (signal to interference noise ratio), increase in the directivity and also increase in the antenna gain, when compared with other RAB algorithms.

scholarly journals Low-Complexity Algorithms for Low Rank Clutter Parameters Estimation in Radar Systems

2016 ◽  
Vol 64 (8) ◽  
pp. 1986-1998 ◽  
Author(s):  
Ying Sun ◽  
Arnaud Breloy ◽  
Prabhu Babu ◽  
Daniel P. Palomar ◽  
Frederic Pascal ◽  
...  
Keyword(s):  
Low Complexity ◽  
Parameters Estimation ◽  
Low Rank ◽  
Radar Systems

scholarly journals Relations Among Some Low-Rank Subspace Recovery Models

2015 ◽  
Vol 27 (9) ◽  
pp. 1915-1950 ◽  
Author(s):  
Hongyang Zhang ◽  
Zhouchen Lin ◽  
Chao Zhang ◽  
Junbin Gao
Keyword(s):  
Principal Component ◽  
Low Complexity ◽  
Formal Proof ◽  
Low Rank ◽  
Filtering Algorithm ◽  
Text Filtering ◽  
Low Rank Representation ◽  
Recovery Models ◽  
Low Rank Models ◽  
Low Dimensional

Recovering intrinsic low-dimensional subspaces from data distributed on them is a key preprocessing step to many applications. In recent years, a lot of work has modeled subspace recovery as low-rank minimization problems. We find that some representative models, such as robust principal component analysis (R-PCA), robust low-rank representation (R-LRR), and robust latent low-rank representation (R-LatLRR), are actually deeply connected. More specifically, we discover that once a solution to one of the models is obtained, we can obtain the solutions to other models in closed-form formulations. Since R-PCA is the simplest, our discovery makes it the center of low-rank subspace recovery models. Our work has two important implications. First, R-PCA has a solid theoretical foundation. Under certain conditions, we could find globally optimal solutions to these low-rank models at an overwhelming probability, although these models are nonconvex. Second, we can obtain significantly faster algorithms for these models by solving R-PCA first. The computation cost can be further cut by applying low-complexity randomized algorithms, for example, our novel [Formula: see text] filtering algorithm, to R-PCA. Although for the moment the formal proof of our [Formula: see text] filtering algorithm is not yet available, experiments verify the advantages of our algorithm over other state-of-the-art methods based on the alternating direction method.

scholarly journals An Efficient Tensor Completion Method Combining Matrix Factorization and Smoothness

2021 ◽  
Vol 2021 ◽  
pp. 1-13
Author(s):  
Leiming Tang ◽  
Xunjie Cao ◽  
Weiyang Chen ◽  
Changbo Ye
Keyword(s):  
Matrix Factorization ◽  
Low Complexity ◽  
Low Rank ◽  
Total Variation Regularization ◽  
Tensor Completion ◽  
Alternating Direction ◽  
Factorization Model ◽  
Efficiency And Effectiveness ◽  
The Matrix ◽  
Accelerate Convergence

In this paper, the low-complexity tensor completion (LTC) scheme is proposed to improve the efficiency of tensor completion. On one hand, the matrix factorization model is established for complexity reduction, which adopts the matrix factorization into the model of low-rank tensor completion. On the other hand, we introduce the smoothness by total variation regularization and framelet regularization to guarantee the completion performance. Accordingly, given the proposed smooth matrix factorization (SMF) model, an alternating direction method of multiple- (ADMM-) based solution is further proposed to realize the efficient and effective tensor completion. Additionally, we employ a novel tensor initialization approach to accelerate convergence speed. Finally, simulation results are presented to confirm the system gain of the proposed LTC scheme in both efficiency and effectiveness.

scholarly journals Exact Low Tubal Rank Tensor Recovery from Gaussian Measurements

2018 ◽  
Author(s):  
Canyi Lu ◽  
Jiashi Feng ◽  
Zhouchen Lin ◽  
Shuicheng Yan
Keyword(s):  
Degrees Of Freedom ◽  
Low Complexity ◽  
Nuclear Norm ◽  
Low Rank ◽  
Robust Pca ◽  
L1 Norm ◽  
Rank Tensor ◽  
Atomic Norm ◽  
Tensor Recovery ◽  
The Matrix

The recent proposed Tensor Nuclear Norm (TNN) [Lu et al., 2016; 2018a] is an interesting convex penalty induced by the tensor SVD [Kilmer and Martin, 2011]. It plays a similar role as the matrix nuclear norm which is the convex surrogate of the matrix rank. Considering that the TNN based Tensor Robust PCA [Lu et al., 2018a] is an elegant extension of Robust PCA with a similar tight recovery bound, it is natural to solve other low rank tensor recovery problems extended from the matrix cases. However, the extensions and proofs are generally tedious. The general atomic norm provides a unified view of low-complexity structures induced norms, e.g., the l1-norm and nuclear norm. The sharp estimates of the required number of generic measurements for exact recovery based on the atomic norm are known in the literature. In this work, with a careful choice of the atomic set, we prove that TNN is a special atomic norm. Then by computing the Gaussian width of certain cone which is necessary for the sharp estimate, we achieve a simple bound for guaranteed low tubal rank tensor recovery from Gaussian measurements. Specifically, we show that by solving a TNN minimization problem, the underlying tensor of size n1×n2×n3 with tubal rank r can be exactly recovered when the given number of Gaussian measurements is O(r(n1+n2−r)n3). It is order optimal when comparing with the degrees of freedom r(n1+n2−r)n3. Beyond the Gaussian mapping, we also give the recovery guarantee of tensor completion based on the uniform random mapping by TNN minimization. Numerical experiments verify our theoretical results.

scholarly journals Quantized compressive sensing with RIP matrices: the benefit of dithering

2019 ◽  
Vol 9 (3) ◽  
pp. 543-586 ◽  
Author(s):  
Chunlei Xu ◽  
Laurent Jacques
Keyword(s):  
Compressive Sensing ◽  
Signal Reconstruction ◽  
Low Complexity ◽  
Reconstruction Error ◽  
Low Rank ◽  
Reconstruction Method ◽  
Single Realization ◽  
Uniform Quantization ◽  
Sensing Model ◽  
Quantized Observations

Abstract Quantized compressive sensing deals with the problem of coding compressive measurements of low-complexity signals with quantized, finite precision representations, i.e., a mandatory process involved in any practical sensing model. While the resolution of this quantization impacts the quality of signal reconstruction, there exist incompatible combinations of quantization functions and sensing matrices that proscribe arbitrarily low reconstruction error when the number of measurements increases. This work shows that a large class of random matrix constructions known to respect the restricted isometry property (RIP) is ‘compatible’ with a simple scalar and uniform quantization if a uniform random vector, or a random dither, is added to the compressive signal measurements before quantization. In the context of estimating low-complexity signals (e.g., sparse or compressible signals, low-rank matrices) from their quantized observations, this compatibility is demonstrated by the existence of (at least) one signal reconstruction method, the projected back projection, whose reconstruction error decays when the number of measurements increases. Interestingly, given one RIP matrix and a single realization of the dither, a small reconstruction error can be proved to hold uniformly for all signals in the considered low-complexity set. We confirm these observations numerically in several scenarios involving sparse signals, low-rank matrices and compressible signals, with various RIP matrix constructions such as sub-Gaussian random matrices and random partial discrete cosine transform matrices.

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