Electrical capacitance tomography image reconstruction based on iterative Tikhonov regularization improved algorithm

doi:https://doi.org/10.1007/s11801-023-3061-6

Home > Archive>Volume 19, Issue 12, 2023 >762-768. DOI:https://doi.org/10.1007/s11801-023-3061-6

Electrical capacitance tomography image reconstruction based on iterative Tikhonov regularization improved algorithm
DOI:
                        https://doi.org/10.1007/s11801-023-3061-6
                    
CSTR:
                        [cstr]
                    
Author:
                        YAN ChunmanYAN Chunman
School of Physics and Electronic Engineering, Northwest Normal University, Lanzhou 730070, China
Find this author on All Journals
Find this author on BaiDu
Search for this author on this site
ZOU MengZOU Meng
School of Physics and Electronic Engineering, Northwest Normal University, Lanzhou 730070, China
Find this author on All Journals
Find this author on BaiDu
Search for this author on this site

                    
Affiliation:School of Physics and Electronic Engineering, Northwest Normal University, Lanzhou 730070, China
Clc Number:
Fund Project:

Article

Figures

Metrics

Reference [17]

Related [20]

Cited by

Materials

Comments

Abstract:

Aiming at the problems of low reconstruction quality, poor robustness, and the inability to quickly and stably converge caused by the ill-posedness of electrical capacitance tomography image reconstruction, an improved algorithm based on iterative Tikhonov regularization (ITR) was proposed. The algorithm constructs a new objective function by introducing the Lp norm to carry out multi-criteria constraints, and introduces the result of the corrected Tikhonov regularization (TR) algorithm into the image reconstruction process together with the logarithmic weight factor as the estimated value. At the same time, an acceleration strategy is used, and the residual term is exponentially filtered. Perform ablation, initial value sensitivity, convergence, and noise interference experiments on the improved algorithm and compare it with other common algorithms. Experimental results show that the improved algorithm can quickly and stably converge and has good robustness and initial value insensitivity. The reconstructed image quality is high, the average correlation coefficient (CC) can reach 0.963 3, and the average relative error (RE) can be reduced to 0.069 4.

Reference

[1] WANG H X. Electrical tomography[M]. 1st ed. Beijing：Science Press, 2013：33-35. (in Chinese)

[2] LI A Q, MENG S, HUANG K, et al. On the concentration models in electrical capacitance tomography for gas-fluidized bed measurements[J]. Chemical engineering journal, 2022, 435：134989.

[3] LIU J, LIU S, SUN S, et al. Internal structure visualization of flow and flame by process tomography and PLIF data fusion[J]. Journal of thermal science, 2018, 27(1)：64-73.

[4] CARCANGIU S, FANNI A, MONTISCI A. Electric capacitance tomography for nondestructive testing of standing trees[J]. International journal of numerical modelling：lectronic networks, devices and fields, 2019, 32(4)：e2252.

[5] ZHAO Y L, GUO B L, YAN Y Y. Research progress and analysis of electrical capacitance tomography[J]. Chinese journal of scientific instrument, 2012, 8： 1909-1920. (in Chinese)

[6] ZHAO J W, YUAN Q P, QIN J, et al. Single image super-resolution reconstruction using multiple dictionaries and improved iterative back-projection[J]. Optoelectronics letters, 2019, 15(2)：156-160.

[7] WANG H X, TANG L, YAN Y. Total variation regularization algorithm for electrical capacitance tomography image reconstruction[J]. Chinese journal of scientific instrument, 2007, 28(11)：2014-2018. (in Chinese)

[8] HUANG D T, HUANG W Q, HUANG H, et al. Application of regularization technique in image super-resolution algorithm via sparse representation[J]. Optoelectronics letters, 2017, 13(6)：439-443.

[9] YAN C M, MU Z, ZHANG D L, et al. ECT image reconstruction based on improved Landweber algorithm[J]. Chinese journal of sensors and actuators, 2019, 32(10)：1522-1526. (in Chinese)

[10] TIAN Z N, GAO X X, QIU L M, et al. Experimental imaging and algorithm optimization based on deep neural network for electrical capacitance tomography for LN2-VN2 flow[J]. Cryogenics, 2022, 127：103568.

[11] TONG G W, LIU S, LIU S. Computationally efficient image reconstruction algorithm for electrical capacitance tomography[J]. Transactions of the institute of measurement & control, 2019, 41(3)：631-646.

[12] LIU J, LIU S, ZHOU W, et al. Flame detection on swirl burner using ECT with dynamic reconstruction algorithm based on the split Bregman iteration[J]. IEEE sensors journal, 2017, 17(22)：7290-7297.

[13] CUI L, TIAN P, WANG C, et al. Iterative weighted fidelity and hybrid regularization-based algorithm for ECT[J]. Measurement science and technology, 2022, 33(6)：065404.

[14] CUI A, PENG J, LI H, et al. Iterative thresholding algorithm based on non-convex method for modified LP-norm regularization minimization[J]. Journal of computational and applied mathematics, 2019, 347：173-180.

[15] ZHAO Q, LIU S, CHAI X, et al. A novel computational imaging algorithm based on split Bregman iterative for electrical capacitance tomography[J]. Measurement science and technology, 2021, 32(12)：125401.

[16] LUO Y H. Research on exponential filter in filtered back projection algorithm for CT image reconstruction[J]. Computer science, 2014, 101：220-223.

[17] YAN C M, MU Z. An improved gradient accelerated Landweber algorithm and its application in ECT image reconstruction[J]. Journal of electronic measurement and instrument, 2021, 35(6)：169-175.

Get Citation

YAN Chunman, ZOU Meng. Electrical capacitance tomography image reconstruction based on iterative Tikhonov regularization improved algorithm[J]. Optoelectronics Letters,2023,19(12):762-768

Copy

Article Metrics

Abstract:213
PDF: 575
HTML: 0
Cited by: 0

History

Received:April 04,2023
Revised:June 04,2023
Adopted:
Online: December 08,2023
Published:

Home

About us

Authors

Editors

News

Contents

Contact us

Get Citation

Share

Article Metrics

History

Article QR Code