Uncertainty prediction of crosstalk measurement for multi-conductor transmission lines

Liting Deng; Longquan Zhong; Qiang Liu; Zihan Sun; Liping Yan; Xiang Zhao

doi:10.11884/HPLPB202133.210066

[1] Yuan K, Grassi F, Spadacini G, et al. Reproducing field-to-wire coupling effects in twisted-wire pairs by crosstalk[J]. IEEE Transactions on Electromagnetic Compatibility, 60, 991-1000(2018).

[2] Zheng Junqi. Electromagic compatibility design test case analysis[M]. Beijing: Publishing House of Electronics Industry, 2010

[3] Dong X, Weng H, Beetner D G, et al. Approximation of worst case crosstalk at high frequencies[J]. IEEE Transactions on Electromagnetic Compatibility, 53, 202-208(2011).

[4] Shan Qin. Research on key technologies of electromagic compatibility f China railway highspeed[D]. Beijing: Beijing Jiaotong University, 2013: 93148

[5] Grassi F, Abdollahi H, Spadacini G, et al. Radiated immunity test involving crosstalk and enforcing equivalence with field-to-wire coupling[J]. IEEE Transactions on Electromagnetic Compatibility, 58, 66-74(2016).

[6] Chabane S, Besnier P, Klingler M. A modified enhanced transmission line theory applied to multiconductor transmission lines[J]. IEEE Transactions on Electromagnetic Compatibility, 59, 1-11(2017).

[7] Rotgerink J L, Schippers H, Leferink F. Low-frequency analysis of multiconductor transmission lines for crosstalk design rules[J]. IEEE Transactions on Electromagnetic Compatibility, 61, 1-9(2018).

[12] Zhang Dan. Research on the predicting modeling method of electromagic compatibility its application f EMUs[D]. Beijing: Beijing Jiaotong University, 2017: 3554

[13] Zhang Xiaoxiao. Research on calculation of crosstalk fieldtowire[D]. Nanjing: Southeast University, 2017: 2348

[14] Paul C R. Solution of the transmission-line equations for three-conductor lines in homogeneous media[J]. IEEE Transactions on Electromagnetic Compatibility, 20, 216-222(1978).

[15] Xiao Pei. Study on modeling calculation method f the electromagic interference of interconnection cable in electromechanical equipment[D]. Chengdu: University of Electronic Science Technology of China, 2019: 4041

[16] Xiu D. Efficient collocational approach for parametric uncertainty analysis[J]. Communications in Computational Physics, 2, 293-309(2007).

[17] Field R V J, Grigoriu M, Emery J M. On the efficacy of stochastic collocation, stochastic Galerkin, and stochastic reduced order models for solving stochastic problems[J]. Probabilistic Engineering Mechanics, 41, 60-72(2015).

[19] Fei Z, Huang Y, Zhou J, et al. Sensitivity analysis of cable crosstalk to uncertain parameters using stochastic reduced der models[C]IEEE International Symposium on Electromagic Compatibility. 2016: 385389.

[20] Fei Z, Huang Y, Zhou J, et al. Uncertainty quantification of crosstalk using stochastic reduced order models[J]. IEEE Transactions on Electromagnetic Compatibility, 59, 228-239(2016).

[22] GBZ 6113.4012018, Specification f radio disturbance immunity measurement equipment measurement methods —Part 41: Uncertainty, statistics limit modeling — Uncertainty in stardized EMC tests[S]