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8 results on '"Ceylan, Omer"'

1. A Low-Noise 320X240 Digital Roic For Sige Microbolometers With A Fast Converging Offset Calibration Technique

Author

Kunnatharayil, Cerin Ninan, Abbasi, Shahbaz, Ceylan, Omer, and Gurbuz, Yasar

Abstract

This paper presents a low-noise 320 x 240 digital readout integrated circuit (ROIC) for SiGe microbolometers with a pitch size of 17 mu m. The ROIC architecture uses a column-shared capacitive transimpedance amplifier (CTIA) that senses the change in resistance of the SiGe microbolometers with respect to the column-shared reference microbolometer pixel. The output voltage of the CTIA is then digitized using a split-successive approximation register (SAR) analog-to-digital converter (ADC). Each 40 columns of the CTIA is connected to a SAR ADC with the help of a 40x1 MUX, which makes 8 parallel-operating ADCs in total. In this way, speed and power requirements of ADCs are relaxed. The offset calibration for the comparator, in the split-SAR ADC is designed using a novel two-step coarse and fine current adjusted technique. The prototype ROIC consumes 118.75 mu W power per column while has an NETD of less than 9mK. Simulation results of the proposed offset-calibration technique offers a minimum conversion time of 71.78 ns with a minimum residual voltage of 42 mu V.

Published
2021

7. Comprehensive Predictive Device Modeling and Analysis of a Si/Si1-xGex Multiquantum-Well Detector.

Author

Shafique, Atia, Abbasi, Shahbaz, Ceylan, Omer, Yamamoto, Yuji, Baristiran Kaynak, Canan, Kaynak, Mehmet, and Gurbuz, Yasar

Subjects
ELECTRICAL engineering, DOPING agents (Chemistry), THERMIONIC emission, TEMPERATURE coefficient of electric resistance, ELECTRONIC equipment
Abstract

This paper presents a predictive device model implemented by a self-consistent solution of Poisson–Schrödinger drift-diffusion formulation for a thermally sensitive detector based on a ${\mathrm {Si/Si}}_{{1}-{x}}{\mathrm {Ge}}_{{x}}$ multiquantum-well structure. The physical phenomena governing the carrier transport were modeled to investigate the effect of physical design aspects (Ge content, well periodicity, and well thickness). In particular, we have analyzed the effect of these physical design parameters on the carrier dynamics quantified by the dc performance in terms of net current density. A fully integrated simulation framework was developed and employed to optimize Ge content and device doping for a desired figure of merits specified by temperature coefficient of resistance (TCR) and dc resistance (${R}$). This methodology was successfully utilized to realize device profiles for various amounts of Ge content and optimization of (${R}$) geared for both high TCR and low noise. The dc performance metrics of the optimized profiles obtained by modeling presented here are compared and validated with the fabricated test devices. [ABSTRACT FROM AUTHOR]

Published
2018
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