Publication result detail

Systematic Approach to the Design of Reconnection-Less Reconfigurable Filters Using the Method of Unknown Nodal Voltages

LANGHAMMER, L.; ŠOTNER, R.

Original Title

Systematic Approach to the Design of Reconnection-Less Reconfigurable Filters Using the Method of Unknown Nodal Voltages

English Title

Systematic Approach to the Design of Reconnection-Less Reconfigurable Filters Using the Method of Unknown Nodal Voltages

Type

WoS Article

Original Abstract

The paper introduces a systematic approach to the design of reconnection-less reconfigurable filters based on the Method of Unknown Nodal Voltages (MUNV). The used approach of previously proposed filters is based on the trial and error (personal experience) selection of parameters of the factorization of the algebraic complements for Laplace expansion of the sub-determinants while the newly proposed approach consists of the gradual placement of individual parameters into the specific matrix element(s) based on the knowledge of which position in the matrix is reflected in particular terms of the transfer function. The proposed approach provides following advantages in comparison to the standard MUNV: a) a more systematic design of MUNV based reconnection-less reconfigurable filters, b) it only requires returning to the selection of signs of individual parameters when the resulting transfer function does not meet its desired form, c) it can be adjusted for different circuits other than reconnection-less reconfigurable filters. The introduced approach is tested and verified for several previously proposed reconnection-less reconfigurable filters (based on MUNV method) and newly presented solution. The possibility to design other circuit types (shown for the design of an oscillator) is also presented. The behavior of the proposed filter is supported by PSpice simulations and experimental measurements in order to verify the design approach.

English abstract

The paper introduces a systematic approach to the design of reconnection-less reconfigurable filters based on the Method of Unknown Nodal Voltages (MUNV). The used approach of previously proposed filters is based on the trial and error (personal experience) selection of parameters of the factorization of the algebraic complements for Laplace expansion of the sub-determinants while the newly proposed approach consists of the gradual placement of individual parameters into the specific matrix element(s) based on the knowledge of which position in the matrix is reflected in particular terms of the transfer function. The proposed approach provides following advantages in comparison to the standard MUNV: a) a more systematic design of MUNV based reconnection-less reconfigurable filters, b) it only requires returning to the selection of signs of individual parameters when the resulting transfer function does not meet its desired form, c) it can be adjusted for different circuits other than reconnection-less reconfigurable filters. The introduced approach is tested and verified for several previously proposed reconnection-less reconfigurable filters (based on MUNV method) and newly presented solution. The possibility to design other circuit types (shown for the design of an oscillator) is also presented. The behavior of the proposed filter is supported by PSpice simulations and experimental measurements in order to verify the design approach.

Keywords

electronic adjustment; frequency filter; method of unknown nodal voltages; reconnection-less reconfiguration

Key words in English

electronic adjustment; frequency filter; method of unknown nodal voltages; reconnection-less reconfiguration

Authors

LANGHAMMER, L.; ŠOTNER, R.

Released

28.08.2025

Periodical

IEEE Access

Volume

13

Number

8

State

United States of America

Pages from

152377

Pages to

152391

Pages count

15

URL

BibTex

@article{BUT198616,
  author="Lukáš {Langhammer} and Roman {Šotner}",
  title="Systematic Approach to the Design of Reconnection-Less Reconfigurable Filters Using the Method of Unknown Nodal Voltages",
  journal="IEEE Access",
  year="2025",
  volume="13",
  number="8",
  pages="152377--152391",
  doi="10.1109/ACCESS.2025.3603673",
  issn="2169-3536",
  url="https://ieeexplore.ieee.org/document/11143217"
}