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16 results on '"Mesri, Alireza"'

1. High gain two-stage amplifier with positive capacitive feedback compensation

Author

Mesri, Alireza, Pirbazari, Mahmoud Mahdipour, Hadidi, Khayrollah, and Khoei, Abdollah

Subjects
Computer Science - Other Computer Science
Abstract

A novel topology for a high gain two-stage amplifier is proposed. The proposed circuit is designed in a way that the non-dominant pole is at output of the first stage. A positive capacitive feedback (PCF) around the second stage introduces a left half plane (LHP) zero which cancels the phase shift introduced by the non-dominant pole, considerably. The dominant pole is at the output node which means that increasing the load capacitance has minimal effect on stability. Moreover, a simple and effective method is proposed to enhance slew rate. Simulation shows that slew rate is improved by a factor of 2.44 using the proposed method. The proposed amplifier is designed in a 0.18um CMOS process. It consumes 0.86mW power from a 1.8V power supply and occupies 3038.5um2 of chip area. The DC gain is 82.7dB and gain bandwidth (GBW) is 88.9 MHz when driving a 5pF capacitive load. Also low frequency CMRR and PSRR+ are 127dB and 83.2dB, respectively. They are 24.8dB and 24.2dB at GBW frequency, which are relatively high and are other important properties of the proposed amplifier. Moreover, Simulations show convenient performance of the circuit in process corners and also presence of mismatch., Comment: 26 pages, 12 figures, 7 tables Accepted for publication in IET Circuits, Devices and Systems

Published
2014
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2. Development of a Smart Wireless Multisensor Platform for an Optogenetic Brain Implant

Author

Cunha, André B., Schuelke, Christin, Mesri, Alireza, Ruud, Simen K., Aizenshtadt, Aleksandra, Ferrari, Giorgio, Heiskanen, Arto, Asif, Afia, Keller, Stephan S., Ramos-Moreno, Tania, Kalvøy, Håvard, Martínez-Serrano, Alberto, Krauss, Stefan, Emnéus, Jenny, Sampietro, Marco, Martinsen, Ørjan G., Cunha, André B., Schuelke, Christin, Mesri, Alireza, Ruud, Simen K., Aizenshtadt, Aleksandra, Ferrari, Giorgio, Heiskanen, Arto, Asif, Afia, Keller, Stephan S., Ramos-Moreno, Tania, Kalvøy, Håvard, Martínez-Serrano, Alberto, Krauss, Stefan, Emnéus, Jenny, Sampietro, Marco, and Martinsen, Ørjan G.

Abstract

Implantable cell replacement therapies promise to completely restore the function of neural structures, possibly changing how we currently perceive the onset of neurodegenerative diseases. One of the major clinical hurdles for the routine implementation of stem cell therapies is poor cell retention and survival, demanding the need to better understand these mechanisms while providing precise and scalable approaches to monitor these cell-based therapies in both pre-clinical and clinical scenarios. This poses significant multidisciplinary challenges regarding planning, defining the methodology and requirements, prototyping and different stages of testing. Aiming toward an optogenetic neural stem cell implant controlled by a smart wireless electronic frontend, we show how an iterative development methodology coupled with a modular design philosophy can mitigate some of these challenges. In this study, we present a miniaturized, wireless-controlled, modular multisensor platform with fully interfaced electronics featuring three different modules: an impedance analyzer, a potentiostat and an optical stimulator. We show the application of the platform for electrical impedance spectroscopy-based cell monitoring, optical stimulation to induce dopamine release from optogenetically modified neurons and a potentiostat for cyclic voltammetry and amperometric detection of dopamine release. The multisensor platform is designed to be used as an opto-electric headstage for future in vivo animal experiments.

Published
2024

3. Development of a Smart Wireless Multisensor Platform for an Optogenetic Brain Implant

Author

European Commission, Research Council of Norway, Cunha, André B., Schuelke, Christin, Mesri, Alireza, Ruud, Simen K., Aizenshtadt, Aleksandra, Ferrari, Giorgio, Heiskanen, Arto, Asif, Afia, Keller, Stephan S., Ramos-Moreno, Tania, Kalvøy, Håvard, Martínez-Serrano, Alberto, Krauss, Stefan, Emnéus, Jenny, Sampietro, Marco, Martinsen, Ørjan G., European Commission, Research Council of Norway, Cunha, André B., Schuelke, Christin, Mesri, Alireza, Ruud, Simen K., Aizenshtadt, Aleksandra, Ferrari, Giorgio, Heiskanen, Arto, Asif, Afia, Keller, Stephan S., Ramos-Moreno, Tania, Kalvøy, Håvard, Martínez-Serrano, Alberto, Krauss, Stefan, Emnéus, Jenny, Sampietro, Marco, and Martinsen, Ørjan G.

Abstract

Implantable cell replacement therapies promise to completely restore the function of neural structures, possibly changing how we currently perceive the onset of neurodegenerative diseases. One of the major clinical hurdles for the routine implementation of stem cell therapies is poor cell retention and survival, demanding the need to better understand these mechanisms while providing precise and scalable approaches to monitor these cell-based therapies in both pre-clinical and clinical scenarios. This poses significant multidisciplinary challenges regarding planning, defining the methodology and requirements, prototyping and different stages of testing. Aiming toward an optogenetic neural stem cell implant controlled by a smart wireless electronic frontend, we show how an iterative development methodology coupled with a modular design philosophy can mitigate some of these challenges. In this study, we present a miniaturized, wireless-controlled, modular multisensor platform with fully interfaced electronics featuring three different modules: an impedance analyzer, a potentiostat and an optical stimulator. We show the application of the platform for electrical impedance spectroscopy-based cell monitoring, optical stimulation to induce dopamine release from optogenetically modified neurons and a potentiostat for cyclic voltammetry and amperometric detection of dopamine release. The multisensor platform is designed to be used as an opto-electric headstage for future in vivo animal experiments.

Published
2024

4. Development of a Smart Wireless Multisensor Platform for an Optogenetic Brain Implant

Author

Cunha, André B., primary, Schuelke, Christin, additional, Mesri, Alireza, additional, Ruud, Simen K., additional, Aizenshtadt, Aleksandra, additional, Ferrari, Giorgio, additional, Heiskanen, Arto, additional, Asif, Afia, additional, Keller, Stephan S., additional, Ramos-Moreno, Tania, additional, Kalvøy, Håvard, additional, Martínez-Serrano, Alberto, additional, Krauss, Stefan, additional, Emnéus, Jenny, additional, Sampietro, Marco, additional, and Martinsen, Ørjan G., additional

Published
2024
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9. High-Value Tunable Pseudo-Resistors Design

Author

Guglielmi, Emanuele, primary, Toso, Fabio, additional, Zanetto, Francesco, additional, Sciortino, Giuseppe, additional, Mesri, Alireza, additional, Sampietro, Marco, additional, and Ferrari, Giorgio, additional

Published
2020
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16. Power and area reduction in CMOS analog fuzzy logic controllers by using a new inference engine structure.

Author

Pirbazari, Mahmoud Mahdipour, Mesri, Alireza, Khoei, Abdollah, and Hadidi, Khayrollah

Subjects
*COMPLEMENTARY metal oxide semiconductors, *MATHEMATICAL simplification, *FUZZY logic, *INFERENCE engines (Computer science), *ENERGY consumption
Abstract

Analog implementation of fuzzy logic controllers (FLCs) is the most efficient method when speed, power, and area are critical. Inference engine (IE) usually takes a large part of total die area when the FLC has a large number of rules. In this paper, a method is proposed to reduce size of the IE in analog implementations of FLCs. Since only a small number of rules may be fired simultaneously, thus a few inference blocks (IBs) may work at the same time in an IE. In the proposed method, reduction in size of the IE is achieved by sharing a few IBs between a large number of rules. To test the proposed method, a standard FLC is designed using both the regular method and the proposed method. By using the proposed method, total power consumption and active area are reduced by factors of 2.31 and 2.15, respectively. Moreover, inference speed is improved by a factor of 3.8 and output error is reduced by a factor of 2.5. All simulations have been performed in HSPICE using level 49 models for 0.35 um CMOS process with a 3.3V power supply. [ABSTRACT FROM AUTHOR]

Published
2015
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