Publication detail

Resistorless Electronically Tunable Grounded Inductance Simulator Design

HERENCSÁR, N. KARTCI, A.

Original Title

Resistorless Electronically Tunable Grounded Inductance Simulator Design

English Title

Resistorless Electronically Tunable Grounded Inductance Simulator Design

Type

conference paper

Language

en

Original Abstract

A new realization of grounded lossless positive inductance simulator (PIS) using simple inverting voltage buffer and unity-gain current follower/inverter (CF±) is reported. Considering the input intrinsic resistance of CF± as useful active parameter, the proposed PIS can be considered as resistorless circuit and it only employs in total 16 Metal-Oxide-Semiconductor (MOS) transistors and a grounded capacitor. The resulting equivalent inductance value of the proposed simulator can be adjusted via change of input intrinsic resistance of CF± by means of its supply voltages. The behavior of the proposed simulator circuit is tested via implementation in voltage-mode 5th-order high-pass filter RLC prototype with Bessel, Butterworth, and Chebyshev I approximation. Theoretical results are verified by SPICE simulations using TSMC 0.18 μm level-7 LO EPI SCN018 CMOS process parameters with ±0.9 V supply voltages.

English abstract

A new realization of grounded lossless positive inductance simulator (PIS) using simple inverting voltage buffer and unity-gain current follower/inverter (CF±) is reported. Considering the input intrinsic resistance of CF± as useful active parameter, the proposed PIS can be considered as resistorless circuit and it only employs in total 16 Metal-Oxide-Semiconductor (MOS) transistors and a grounded capacitor. The resulting equivalent inductance value of the proposed simulator can be adjusted via change of input intrinsic resistance of CF± by means of its supply voltages. The behavior of the proposed simulator circuit is tested via implementation in voltage-mode 5th-order high-pass filter RLC prototype with Bessel, Butterworth, and Chebyshev I approximation. Theoretical results are verified by SPICE simulations using TSMC 0.18 μm level-7 LO EPI SCN018 CMOS process parameters with ±0.9 V supply voltages.

Keywords

Positive inductance simulator; PIS; grounded lossless circuit; current follower; inverting voltage buffer; 5th-order high-pass filter; RLC prototype; Bessel; Butterworth; Chebyshev I; voltage-mode

Released

05.07.2017

Publisher

IEEE

Location

Barcelona, Spain

ISBN

978-1-5090-3982-1

Book

Proceedings of the 2017 40th International Conference on Telecommunications and Signal Processing (TSP)

Pages from

279

Pages to

282

Pages count

4

URL

Full text in the Digital Library

Documents

BibTex


@inproceedings{BUT138294,
  author="Norbert {Herencsár} and Aslihan {Kartci}",
  title="Resistorless Electronically Tunable Grounded Inductance Simulator Design",
  annote="A new realization of grounded lossless positive inductance simulator (PIS) using simple inverting voltage buffer and unity-gain current follower/inverter (CF±) is reported. Considering the input intrinsic resistance of CF± as useful active parameter, the proposed PIS can be considered as resistorless circuit and it only employs in total 16 Metal-Oxide-Semiconductor (MOS) transistors and a grounded capacitor. The resulting equivalent inductance value of the proposed simulator can be adjusted via change of input intrinsic resistance of CF± by means of its supply voltages. The behavior of the proposed simulator circuit is tested via implementation in voltage-mode 5th-order high-pass filter RLC prototype with Bessel, Butterworth, and Chebyshev I approximation. Theoretical results are verified by SPICE simulations using TSMC 0.18 μm level-7 LO EPI SCN018 CMOS process parameters with ±0.9 V supply voltages.",
  address="IEEE",
  booktitle="Proceedings of the 2017 40th International Conference on Telecommunications and Signal Processing (TSP)",
  chapter="138294",
  doi="10.1109/TSP.2017.8075987",
  howpublished="online",
  institution="IEEE",
  year="2017",
  month="july",
  pages="279--282",
  publisher="IEEE",
  type="conference paper"
}