Control Systems and Computers, N5, 2016, Article 2
DOI: https://doi.org/10.15407/usim.2016.05.010
Upr. sist. maš., 2016, Issue 5 (265), pp. 10-24.
UDC 004.942+6232.454.862
E.G. Revunova, PhD in Technical Sciences, Deputy Director on Research, International Research and Training Center for Information Technologies and Systems of the NAS and MES of Ukraine, Glushkov ave., 40, Kyiv, 03187, Ukraine, E-mail: helab@i.com.ua
Recovering Signals Obtained by Indirect Measurements Based on Truncated Singular Value Decomposition and Random Projection
Introduction. The solution of the ill-posed inverse problem by the least squares method is unstable with a large solution error. Tikhonov regularization, truncated singular value decomposition, and random projection were used to overcome the instability and to increase the accuracy of the solution.
Purpose. We provide an experimental comparison of the solution accuracy for the ill-posed inverse problem by Tikhonov regularization, truncated singular value decomposition, and random projection.
Methods. Tikhonov’s regularization imposes some restrictions on the solution, i.e. penalty on its Euclidean norm, that improves stability. Another approach approximates the original data by a model linear with respect to parameters. Selection of the optimal number of components of the linear model minimizes the error of solution and ensures stability. To obtain the optimal number of model components, model selection criteria are used.
Results and Conclusion. A comparative analysis of the accuracy shows that the truncated singular value decomposition method with the CRSVD criterion and the random projection method with the CRQ and AIC criteria ensured the accuracy at the level of Tikhonov regularization with the regularization parameter selected by the discrepancy method. The advantage of the random projection method is a lower computational complexity due to the dimensionality reduction.
Perspective. The directions for further research include the decreasing of the computational complexity and averaging over the realizations of the random matrix.
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Keywords: discrete ill-posed problem, regularization, truncated singular value decomposition, random projection.
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Received 09.04.2015