Modeling and simulation of an instrumentation amplifier in high temperature using a VHDL-AMS op-amp model

Background: Sensing of biomedical signals is crucial for monitoring of various health conditions. These signals have a very low amplitude (in μV) and a small frequency range (<500 Hz). In the presence of various common-mode interferences, biomedical signals are difficult to detect. Instrumentation amplifiers (INAs) are usually preferred to detect these signals due to their high commonmode rejection ratio (CMRR). Gain accuracy and CMRR are two important parameters associated with any INA. This article, therefore, focuses on the improvement of the gain accuracy and CMRR of a low power INA topology. Objective: The objective of this article is to achieve high gain accuracy and CMRR of low power INA by having high gain operational amplifiers (Op-Amps), which are the building blocks of the INAs. Methods: For the implementation of the Op-Amps and the INAs, the Cadence Virtuoso tool was used. All the designs and implementation were realized in 0.18 μm CMOS technology. Results: Three different Op-Amp topologies namely single-stage differential Op-Amp, folded cascode Op-Amp, and multi-stage Op-Amp were implemented. Using these Op-Amp topologies separately, three Op-Amp-based INAs were realized and compared. The INA designed using the high gain multistage Op-Amp topology of low-frequency gain of 123.89 dB achieves a CMRR of 164.1 dB, with the INA’s gain accuracy as good as 99%, which is the best when compared to the other two INAs realized using the other two Op-Amp topologies implemented. Conclusion: Using very high gain Op-Amps as the building blocks of the INA improves the gain accuracy of the INA and enhances the CMRR of the INA. The three Op-Amp-based INA designed with the multi-stage Op-Amps shows state-of-the-art characteristics as its gain accuracy is 99% and CMRR is as high as 164.1 dB. The power consumed by this INA is 29.25 μW by operating on a power supply of ±0.9V. This makes this INA highly suitable for low power measurement applications.

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Kinetic modeling and simulation of high-temperature by-product formation from urea decomposition

Chemical Engineering Science ◽

10.1016/j.ces.2021.116876 ◽

2021 ◽

pp. 116876

Author(s):

C. Kuntz ◽

C. Kuhn ◽

H. Weickenmeier ◽

S. Tischer ◽

M. Börnhorst ◽

...

Keyword(s):

High Temperature ◽

Modeling And Simulation ◽

Kinetic Modeling ◽

Product Formation ◽

Urea Decomposition

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An improved AC-amplifier for electrophysiology

Journal of Automatic Control ◽

10.2298/jac0901007j ◽

2009 ◽

Vol 19 (1) ◽

pp. 7-12

Author(s):

Nikola Jorgovanovic ◽

Dubravka Bojanic ◽

Vojin Ilic ◽

Darko Stanisic

Keyword(s):

Dynamic Range ◽

Cutoff Frequency ◽

Instrumentation Amplifier ◽

Single Chip ◽

Common Mode ◽

Differential Signal ◽

Op Amp ◽

Chip Technology ◽

The Common ◽

Dc Component

We present the design, simulation and test results of a new AC amplifier for electrophysiological measurements based on a three op-amp instrumentation amplifier (IA). The design target was to increase the common mode rejection ratio (CMRR), thereby improving the quality of the recorded physiological signals in a noisy environment. The new amplifier actively suppresses the DC component of the differential signal and actively reduces the common mode signal in the first stage of the IA. These functions increase the dynamic range of the amplifier's first stage of the differential signal. The next step was the realization of the amplifier in a single chip technology. The design and tests of the new AC amplifier with a differential gain of 79.2 dB, a CMRR of 130 dB at 50 Hz, a high-pass cutoff frequency at 0.01 Hz and common mode reduction in the first stage of the 49.8 dB are presented in this paper.

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