Singular Value Decomposition for Compression of Large-Scale Radio Frequency Signals

Online Education ◽

Recommender Systems ◽

Matrix Factorization ◽

Gradient Descent ◽

Large Scale ◽

Singular Value ◽

Factorization Algorithms ◽

Value Decomposition ◽

Interaction History

Recommender systems aim to personalize the experience of user by suggesting items to the user based on the preferences of a user. The preferences are learned from the user’s interaction history or through explicit ratings that the user has given to the items. The system could be part of a retail website, an online bookstore, a movie rental service or an online education portal and so on. In this paper, I will focus on matrix factorization algorithms as applied to recommender systems and discuss the singular value decomposition, gradient descent-based matrix factorization and parallelizing matrix factorization for large scale applications.

Split-and-Combine Singular Value Decomposition for Large-Scale Matrix

Journal of Applied Mathematics ◽

10.1155/2013/683053 ◽

2013 ◽

Vol 2013 ◽

pp. 1-8 ◽

Cited By ~ 6

Author(s):

Jengnan Tzeng

Keyword(s):

Large Scale ◽

Semantic Analysis ◽

Computational Cost ◽

Matrix Decomposition ◽

Singular Value ◽

Fast Method ◽

The Matrix ◽

Scale Matrix ◽

The singular value decomposition (SVD) is a fundamental matrix decomposition in linear algebra. It is widely applied in many modern techniques, for example, high- dimensional data visualization, dimension reduction, data mining, latent semantic analysis, and so forth. Although the SVD plays an essential role in these fields, its apparent weakness is the order three computational cost. This order three computational cost makes many modern applications infeasible, especially when the scale of the data is huge and growing. Therefore, it is imperative to develop a fast SVD method in modern era. If the rank of matrix is much smaller than the matrix size, there are already some fast SVD approaches. In this paper, we focus on this case but with the additional condition that the data is considerably huge to be stored as a matrix form. We will demonstrate that this fast SVD result is sufficiently accurate, and most importantly it can be derived immediately. Using this fast method, many infeasible modern techniques based on the SVD will become viable.

A fast algorithm for regularized focused 3D inversion of gravity data using randomized singular-value decomposition

Geophysics ◽

10.1190/geo2017-0386.1 ◽

2018 ◽

Vol 83 (4) ◽

pp. G25-G34 ◽

Cited By ~ 9

Author(s):

Saeed Vatankhah ◽

Rosemary Anne Renaut ◽

Vahid Ebrahimzadeh Ardestani

Keyword(s):

Linear System ◽

Fast Algorithm ◽

Large Scale ◽

Gravity Data ◽

Singular Values ◽

Singular Value ◽

System Matrix ◽

Large Scale System ◽

We develop a fast algorithm for solving the under-determined 3D linear gravity inverse problem based on randomized singular-value decomposition (RSVD). The algorithm combines an iteratively reweighted approach for [Formula: see text]-norm regularization with the RSVD methodology in which the large-scale linear system at each iteration is replaced with a much smaller linear system. Although the optimal choice for the low-rank approximation of the system matrix with [Formula: see text] rows is [Formula: see text], acceptable results are achievable with [Formula: see text]. In contrast to the use of the iterative LSQR algorithm for the solution of linear systems at each iteration, the singular values generated using RSVD yield a good approximation of the dominant singular values of the large-scale system matrix. Thus, the regularization parameter found for the small system at each iteration is dependent on the dominant singular values of the large-scale system matrix and appropriately regularizes the dominant singular space of the large-scale problem. The results achieved are comparable with those obtained using the LSQR algorithm for solving each linear system, but they are obtained at a reduced computational cost. The method has been tested on synthetic models along with real gravity data from the Morro do Engenho complex in central Brazil.

Modified truncated randomized singular value decomposition (MTRSVD) algorithms for large scale discrete ill-posed problems with general-form regularization

Inverse Problems ◽

10.1088/1361-6420/aab92d ◽

2018 ◽

Vol 34 (5) ◽

pp. 055013 ◽

Cited By ~ 3

Author(s):

Zhongxiao Jia ◽

Yanfei Yang

Keyword(s):

Large Scale ◽

Singular Value ◽

Ill Posed ◽

Receiver phase alignment using fitted SVD derived sensitivities from routine prescans

PLoS ONE ◽

10.1371/journal.pone.0256700 ◽

2021 ◽

Vol 16 (8) ◽

pp. e0256700

Author(s):

Olivia W. Stanley ◽

Ravi S. Menon ◽

L. Martyn Klassen

Keyword(s):

Radio Frequency ◽

Signal To Noise Ratio ◽

Singular Value ◽

7 Tesla ◽

Signal To Noise ◽

Phase Signal ◽

Noise Ratio ◽

Value Decomposition ◽

Svd Method

Magnetic resonance imaging radio frequency arrays are composed of multiple receive coils that have their signals combined to form an image. Combination requires an estimate of the radio frequency coil sensitivities to align signal phases and prevent destructive interference. At lower fields this can be accomplished using a uniform physical reference coil. However, at higher fields, uniform volume coils are lacking and, when available, suffer from regions of low receive sensitivity that result in poor sensitivity estimation and combination. Several approaches exist that do not require a physical reference coil but require manual intervention, specific prescans, or must be completed post-acquisition. This makes these methods impractical for large multi-volume datasets such as those collected for novel types of functional MRI or quantitative susceptibility mapping, where magnitude and phase are important. This pilot study proposes a fitted SVD method which utilizes existing combination methods to create a phase sensitive combination method targeted at large multi-volume datasets. This method uses any multi-image prescan to calculate the relative receive sensitivities using voxel-wise singular value decomposition. These relative sensitivities are fitted to the solid harmonics using an iterative least squares fitting algorithm. Fits of the relative sensitivities are used to align the phases of the receive coils and improve combination in subsequent acquisitions during the imaging session. This method is compared against existing approaches in the human brain at 7 Tesla by examining the combined data for the presence of singularities and changes in phase signal-to-noise ratio. Two additional applications of the method are also explored, using the fitted SVD method in an asymmetrical coil and in a case with subject motion. The fitted SVD method produces singularity-free images and recovers between 95–100% of the phase signal-to-noise ratio depending on the prescan data resolution. Using solid harmonic fitting to interpolate singular value decomposition derived receive sensitivities from existing prescans allows the fitted SVD method to be used on all acquisitions within a session without increasing exam duration. Our fitted SVD method is able to combine imaging datasets accurately without supervision during online reconstruction.

Implementation of SVD Parallel Algorithm and its Application in Medical Industry

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.743.515 ◽

2015 ◽

Vol 743 ◽

pp. 515-521 ◽

Cited By ~ 3

Author(s):

You Wu ◽

Lei Feng Liu ◽

Xue Liang Zhao ◽

Kun Hua Zhong

Keyword(s):

Large Scale ◽

Medical Industry ◽

Singular Value ◽

Construction Process ◽

Time Cost ◽

Scale Matrix ◽

Value Decomposition ◽

Speed And Accuracy ◽

Computing Speed

Singular value decomposition (SVD) is an important part of the numerical calculateion.It is widely used in biology, meteorology, quantum mechanics and other fields. It is discovered that the speed of calculation and accuracy has become the two basic questions of singular value decomposition during the construction process. With the era of big data,there are more and more cases of largescale data analysis using SVD. Singular value decomposition was originally an algorithm for computing resources are consumed, if still using the traditional stand-alone mode, will consume a lot of time cost. In order to improve the computing speed and accuracy, the system implement the parallel SVD algorithm which is based on unilateral jacobi method.It is used to analyze large-scale matrix about medicine for finding similarity of medicine efficacy.

Rotational Speed-Dependent Contact Formulation for Nonlinear Blade Dynamics Prediction

Volume 7C: Structures and Dynamics ◽

10.1115/gt2018-75290 ◽

2018 ◽

Author(s):

Torsten Heinze ◽

Lars Panning-von Scheidt ◽

Jörg Wallaschek ◽

Andreas Hartung

Keyword(s):

Rotational Speed ◽

Large Scale ◽

Vibrational Analysis ◽

Harmonic Balance Method ◽

Singular Value ◽

Nonlinear Frequency ◽

Computational Performance ◽

Contact Situation ◽

Considering rotational speed-dependent stiffness for vibrational analysis of friction-damped bladed disk models has proven to lead to significant improvements in nonlinear frequency response curve computations. The accuracy of the result is driven by a suitable choice of reduction bases. Multi-model reduction combines various bases which are valid for different parameter values. This composition reduces the solution error drastically. The resulting set of equations is typically solved by means of the harmonic balance method. Nonlinear forces are regularized by a Lagrangian approach embedded in an alternating frequency/time domain method providing the Fourier coefficients for the frequency domain solution. The aim of this paper is to expand the multi-model approach to address rotational speed-dependent contact situations. Various reduction bases derived from composing Craig-Bampton, Rubin-Martinez, and hybrid interface methods will be investigated with respect to their applicability to capture the changing contact situation correctly. The methods validity is examined based on small academic examples as well as large-scale industrial blade models. Coherent results show that the multi-model composition works successfully, even if multiple different reduction bases are used per sample point of variable rotational speed. This is an important issue in case that a contact situation for a specific value of the speed is uncertain forcing the algorithm to automatically choose a suitable basis. Additionally, the randomized singular value decomposition is applied to rapidly extract an appropriate multi-model basis. This approach improves the computational performance by orders of magnitude compared to the standard singular value decomposition, while preserving the ability to provide a best rank approximation.