Tracking Analysis of Maximum Versoria Criterion Based Adaptive Filter

被引:1
作者
Khalili, Azam [1 ]
Rastegarnia, Amir [1 ]
Farzamnia, Ali [2 ]
Sanei, Saeid [3 ]
Alghamdi, Thamer A. H. [4 ,5 ]
机构
[1] Malayer Univ, Dept Elect Engn, Malayer 6571995863, Iran
[2] Univ Malaysia Sabah, Fac Engn, Kota Kinabalu 88400, Malaysia
[3] Imperial Coll London, Dept Elect & Elect Engn, London SW7 2AZ, England
[4] Al Baha Univ, Fac Engn, Comp Engn Dept, Al Bahah 65779, Saudi Arabia
[5] Cardiff Univ, Wolfson Ctr Magnet, Sch Engn, Cardiff CF24 3AA, England
来源
IEEE ACCESS | 2024年 / 12卷
关键词
Adaptive filters; Steady-state; Filtering algorithms; Cost function; Information filters; Symbols; Gaussian noise; Robustness; Performance analysis; Tracking; Adaptive filter; non-stationary; performance analysis; tracking; Versoria; RISK-SENSITIVE LOSS; STEADY-STATE; CORRENTROPY; ALGORITHM;
D O I
10.1109/ACCESS.2024.3370471
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Recently, maximum Versoria criterion-based adaptive algorithms have been introduced as a new solution for robust adaptive filtering. This paper studies the steady-state tracking analysis of an adaptive filter with maximum Versoria criterion (MVC) in a non-stationary (Markov time-varying) system. Our analysis relies on the energy conservation method. Both Gaussian and general non-Gaussian noise are considered, and for both cases, the closed-form expression for steady-state excess mean square error (EMSE) is derived. Regardless of noise type, unlike the stationary environment, the EMSE curves are not increasing functions of step-size parameter. The validity of the theoretical results is justified via simulation.
引用
收藏
页码:30747 / 30753
页数:7
相关论文
共 50 条
[41]   Steady-State Performance Analysis of the Nearest Kronecker Product Decomposition Based LMS Adaptive Algorithm [J].
Li, Lei ;
Zheng, Yunfei ;
Guo, Zhongyuan ;
Qian, Guobing ;
Wang, Shiyuan .
IEEE SIGNAL PROCESSING LETTERS, 2025, 32 :1995-1999
[42]   Adaptive FastIMM filter for tracking a maneuvering target using nonlinear measurements [J].
Meche, Abdelkrim ;
Dahmani, Mohammed ;
Keche, Mokhtar .
2017 SEMINAR ON DETECTION SYSTEMS ARCHITECTURES AND TECHNOLOGIES (DAT), 2017,
[43]   Maximum versoria criterion applied to hybrid active noise control algorithm for the impulsive noise [J].
Zhang, Rui ;
Cheng, Yabing ;
Chen, Shuming .
JOURNAL OF LOW FREQUENCY NOISE VIBRATION AND ACTIVE CONTROL, 2023, 42 (04) :1743-1764
[44]   Maximum Correntropy Criterion-Newton Algorithm for Adaptive Interpolated Volterra Filter [J].
Deng, Tao ;
Lu, Lu ;
Zhu, Guangya .
IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT, 2025, 74
[45]   Weighted Maximum Correntropy Criterion-Based Interacting Multiple-Model Filter for Maneuvering Target Tracking [J].
Huai, Liangliang ;
Li, Bo ;
Yun, Peng ;
Song, Chao ;
Wang, Jiayuan .
REMOTE SENSING, 2023, 15 (18)
[46]   Robust Widely Nonlinear Quaternion Volterra Adaptive Filter Based on Recursive General Barron Algorithm and its Performance Analysis [J].
Liu, Qianqian ;
Yan, Han .
IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS II-EXPRESS BRIEFS, 2024, 71 (07) :3578-3582
[47]   Variable Step-Size Affine Projection Maximum Correntropy Criterion Adaptive Filter With Correntropy Induced Metric for Sparse System Identification [J].
Zhao, Haiquan ;
Liu, Bing ;
Song, Pucha .
IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS II-EXPRESS BRIEFS, 2020, 67 (11) :2782-2786
[48]   A generalized maximum correntropy criterion based robust sparse adaptive room equalization [J].
Kumar, Krishna ;
George, Nithin V. .
APPLIED ACOUSTICS, 2020, 158
[49]   Quaternion Recursive Maximum Correntropy and Versoria Criterion Algorithm for Channel Estimation Under Impulsive Noise [J].
Ranjan, Ayush ;
Yadav, Shivam ;
Jain, Sandesh ;
Mitra, Rangeet ;
Uysal, Murat .
IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS I-REGULAR PAPERS, 2025, 72 (08) :4209-4222
[50]   Robust proportionate adaptive filter based on maximum correntropy criterion for sparse system identification in impulsive noise environments [J].
Wentao Ma ;
Dongqiao Zheng ;
Zhiyu Zhang ;
Jiandong Duan ;
Badong Chen .
Signal, Image and Video Processing, 2018, 12 :117-124
12345