The Experts below are selected from a list of 10635 Experts worldwide ranked by ideXlab platform
Paul Heremans - One of the best experts on this subject based on the ideXlab platform.
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analog techniques for reliable organic circuit design on foil applied to an 18 db single stage Differential Amplifier
Organic Electronics, 2010Co-Authors: Hagen Marien, Michiel Steyaert, Erik Van Veenendaal, Paul HeremansAbstract:Abstract In this work we present design strategies for organic Vt-insensitive circuit design tailored to organic p-type transistor technology, and we demonstrate them by application on a single-stage Differential Amplifier. Specifically, to reduce the Vt-sensitivity, we implement common-mode feedback, bootstrapped gain enhancement, cascoding and backgate steering. The effectiveness of the design strategies is demonstrated by showing a single-stage Amplifier performing with 18 dB gain and losing only 4 dB gain after several months of exposure to ambient environment.
Hagen Marien - One of the best experts on this subject based on the ideXlab platform.
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analog techniques for reliable organic circuit design on foil applied to an 18 db single stage Differential Amplifier
Organic Electronics, 2010Co-Authors: Hagen Marien, Michiel Steyaert, Erik Van Veenendaal, Paul HeremansAbstract:Abstract In this work we present design strategies for organic Vt-insensitive circuit design tailored to organic p-type transistor technology, and we demonstrate them by application on a single-stage Differential Amplifier. Specifically, to reduce the Vt-sensitivity, we implement common-mode feedback, bootstrapped gain enhancement, cascoding and backgate steering. The effectiveness of the design strategies is demonstrated by showing a single-stage Amplifier performing with 18 dB gain and losing only 4 dB gain after several months of exposure to ambient environment.
D. M. Gookin - One of the best experts on this subject based on the ideXlab platform.
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Integrated Large Optical Differential Amplifier with Dynamic Range for Gigahertz Bandwidth Electrical Signals
1991Co-Authors: M. H. Berry, D. M. GookinAbstract:A Differential Amplifier for gigahertz bandwidth electrical signals using fiber optics and integrated optical devices was demon- strated. The Differential gain was a function of the electrical to optical and optical to electrical conversion factors. The common mode rejection ratio of our Differential Amplifier at 1 GHz was greater than 30 dB. The common mode rejection ratio depended on the time difference between the Differential Amplifier inputs. This device could be used as an inte- grated module in radar and communications systems.
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Integrated optical Differential Amplifier with large dynamic range for gigahertz bandwidth electrical signals
IEEE Photonics Technology Letters, 1991Co-Authors: M. H. Berry, D. M. GookinAbstract:An optoelectronic Differential Amplifier for gigahertz-bandwidth electrical signals using fiber optics and integrated optical devices is presented. In the Amplifier presented the signal subtraction is done while still in the optical domain. The Differential gain is a function of the electrical-to-optical and optical-to-electrical conversion factors. The common-mode rejection ratio of the Differential Amplifier at 1 GHz is greater than 30 dB. The common-mode rejection ratio depends on the time difference between the Differential Amplifier inputs. This device could be used as an integrated module in radar and communications systems. >
Michiel Steyaert - One of the best experts on this subject based on the ideXlab platform.
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analog techniques for reliable organic circuit design on foil applied to an 18 db single stage Differential Amplifier
Organic Electronics, 2010Co-Authors: Hagen Marien, Michiel Steyaert, Erik Van Veenendaal, Paul HeremansAbstract:Abstract In this work we present design strategies for organic Vt-insensitive circuit design tailored to organic p-type transistor technology, and we demonstrate them by application on a single-stage Differential Amplifier. Specifically, to reduce the Vt-sensitivity, we implement common-mode feedback, bootstrapped gain enhancement, cascoding and backgate steering. The effectiveness of the design strategies is demonstrated by showing a single-stage Amplifier performing with 18 dB gain and losing only 4 dB gain after several months of exposure to ambient environment.
Erik Van Veenendaal - One of the best experts on this subject based on the ideXlab platform.
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analog techniques for reliable organic circuit design on foil applied to an 18 db single stage Differential Amplifier
Organic Electronics, 2010Co-Authors: Hagen Marien, Michiel Steyaert, Erik Van Veenendaal, Paul HeremansAbstract:Abstract In this work we present design strategies for organic Vt-insensitive circuit design tailored to organic p-type transistor technology, and we demonstrate them by application on a single-stage Differential Amplifier. Specifically, to reduce the Vt-sensitivity, we implement common-mode feedback, bootstrapped gain enhancement, cascoding and backgate steering. The effectiveness of the design strategies is demonstrated by showing a single-stage Amplifier performing with 18 dB gain and losing only 4 dB gain after several months of exposure to ambient environment.