Definition of weight coefficient in two-stage automatic compensation based on LMS-algorithm and interference correlation characteristics

Authors

  • S. Ya. Zhuk National Technical University of Ukraine, Kyiv Politechnic Institute, Kiev http://orcid.org/0000-0002-0046-8450
  • K. M. Semibalamut Eugene Bereznyak Military-Diplomatic Academy, Kyiv

DOI:

https://doi.org/10.20535/RADAP.2016.65.26-39

Keywords:

automatic interference compensators, the method of least squares, LMS -algorithm

Abstract

Introduction. Two-stage digital automatic compensators of active noise interference based on LS and RLS-algorithms provide parallel processing of signals and capability to connect/disconnect additional compensation channel block. LMS-algorithm is widely used for synthesis of digital automatic compensators of active noise interference. Its advantage is low computational cost. When solving certain practical problems correlation characteristics of interference signals are either given or their estimates are obtained.
Problem statement. The first stage of the two-stage digital automatic compensator provides compensation of interference in the main channel using compensation channel signals of one of the blocks and orthogonalization of signals in the other block. The second stage provides compensation of the residue interference using the obtained orthogonalized signals. Modules of the first and the second stage are single type weight totalizers. We need to determine weight coeeficient of the two-stage digital automatic compensator with orthogonalization of signals of part of compensation channels based on LMS-algorithms and interference correlation characteristics.
Using LMS-algorithm there was obtained two-stage digital automatic compensator with orthogonalization of part of compensation channels that is quasi-optimal regarding the criterion of minimum mean square error and it’s feature is lower computational complexity compared to two-stage digital automatic compensators based on LS and RLS-algorithms. It can operate in modes when preocessing of the complete training package of the input data is carried out in the first and then in the second stage as well as in the mode of simultaneous operation of the stages.
There have been acheived analytical expressions for defining weight coefficients of modules in the first and in the second stage of the automatic compensator determined on the basis of selective and precisely known correlation characteristics of input interference signals.
LMS-method based two-stage digital automatic compensator efficiency analysis with simultaneously operating stages and its comparison with a known one-stage automatic compensator with the same number of compensation channels were conducted with the help of static modeling at various conditions of interference correlation matrix and various numbers of interference sources.
Conclusions. The obtained two-stage digital automatic compensator with orthogonalization of part of compensation channels is quasi-optimal regarding the criterion of minimum mean square error and it has lower computational complexity compared to two-stage digital automatic compensators based on LS and RLS-algorithms. Weight coefficients of the automatic compensators determined on the basis of selective and precisely known correlation characteristics of input interference signals are optimal regarding the criterion of least squares and minimum mean square error respectively. The obtained two-stage digital automatic compensators provide capability to connect/disconnect additional compensation channel block and appropriate computational stage modules proportionately to the interference situation.

Author Biographies

S. Ya. Zhuk, National Technical University of Ukraine, Kyiv Politechnic Institute, Kiev

Zhuk S. Ya.

K. M. Semibalamut, Eugene Bereznyak Military-Diplomatic Academy, Kyiv

Semibalamut K. M.

References

Список источников

Monzingo R. A. Introduction to adaptive arrays. 2nd ed. / R. A. Monzingo, R. L. Haupt, T. W. Miller. – Scitech publishing, 2011. – 510 p. doi: 10.1049/sbew046e

Ратынский М. В. Адаптация и сверхразрешение в антенных решетках / М. В. Ратынский. – М. : Радио и связь, 2003. – 200 с.

Жук С.Я. Двухступенчатая адаптивная компенсация активных шумовых помех с ортогонализацией сигналов части компенсационных каналов / С. Я. Жук, К. М. Семибаламут // Вестник НТУУ “КПИ”. Серия Радиотехника, Радиоаппаратостроение. – 2016. – № 64. – С. 61-74.

Джиган В. И. Адаптивная фильтрация сигналов: теория и алгоритмы / В. И. Джиган. – М. : Техносфера, 2013. – 528 с.

Гантмахер Ф. Р. Теория матриц / Ф. Р. Гантмахер. – М. : Физматлит, 2004. – 560 с.

References

Monzingo R. A., Haupt R. L. and Miller T. W. (2011) Introduction to adaptive arrays. 2nd ed., Scitech publishing, 510 p. doi: 10.1049/sbew046e

Ratynskii M. V. (2003) Adaptatsiya i sverkhrazreshenie v antennykh reshetkakh [Adaptation and superresolution in antenna arrays]. Moskow, Radio i svyaz', 200 p.

Zhuk, S. Ya., Semibalamut, K. M. (2016) Two-stage adaptive compensation of active noise interference with signals orthogonalization of a part of compensation channels. Visn. NTUU KPI, Ser. Radioteh. radioaparatobuduv., no. 64, pp. 61-74. (in Russian).

Dzhigan V. I. (2013) Adaptivnaya fil'tratsiya signalov: teoriya i algoritmy [Adaptive Signal Filtering: Theory and Algorithms]. Moskow, Tekhnosfera, 528 p.

Gantmakher F. R. (2004) Teoriya matrits [The theory of matrices]. Moskow, Fizmatlit, 560 p.

Published

2016-06-30

How to Cite

Жук, С. Я. and Семибаламут, К. М. (2016) “Definition of weight coefficient in two-stage automatic compensation based on LMS-algorithm and interference correlation characteristics”, Visnyk NTUU KPI Seriia - Radiotekhnika Radioaparatobuduvannia, 0(65), pp. 26-39. doi: 10.20535/RADAP.2016.65.26-39.

Issue

Section

Computing methods in radio electronics