Publication detail

Reconfigurable First-Order Filter Operating with Non-Ideal Parameters of Active Elements

ŽÁK, T. ŠOTNER, R. JEŘÁBEK, J. VRBA, K. DOSTÁL, T.

Original Title

Reconfigurable First-Order Filter Operating with Non-Ideal Parameters of Active Elements

Type

conference paper

Language

English

Original Abstract

This contribution present way how to improve the finite attenuation in the stop band in the case of particular transfer function of the specific filtering structure. It is an important problem in the field of active filters. Real non-ideal model (including small-signal parasitic influences caused by real active elements) of the electronically reconfigurable reconnection-less filter is studied in configuration when the most affected transfer function is used (high-pass response in our case). Symbolical analyses of ideal and influenced transfer function and sensitivity analyses in Matlab provide information how to improve level of stop-band attenuation by available parameters even under condition of really unsuitable terminal resistances (output resistances) of active elements used.

Keywords

Active filter; electronic control; finite stop-band attenuation; real behavior; reconfigurable transfer function; small-signal modeling

Authors

ŽÁK, T.; ŠOTNER, R.; JEŘÁBEK, J.; VRBA, K.; DOSTÁL, T.

RIV year

2015

Released

8. 9. 2015

Publisher

Západočeská univerzita v Plzni

Location

Plzeň

ISBN

978-80-261-0385-1

Book

2015 International Conference on Applied Electronics

Pages from

293

Pages to

296

Pages count

4

URL

BibTex

@inproceedings{BUT116183,
  author="Tomáš {Žák} and Roman {Šotner} and Jan {Jeřábek} and Kamil {Vrba} and Tomáš {Dostál}",
  title="Reconfigurable First-Order Filter Operating with Non-Ideal Parameters of Active Elements",
  booktitle="2015 International Conference on Applied Electronics",
  year="2015",
  pages="293--296",
  publisher="Západočeská univerzita v Plzni",
  address="Plzeň",
  isbn="978-80-261-0385-1",
  url="https://ieeexplore.ieee.org/document/7301108"
}