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Your search keyword '"Mitra Mirhassani"' showing total 135 results
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135 results on '"Mitra Mirhassani"'

1. A Varactor-Less DCO With $7~GHz$ Tuning Range for $77~GHz$ Automotive Radars

Author

Iman Taha and Mitra Mirhassani

Subjects
Digitally controlled oscillator (DCO), frequency resolution, millimeter-wave frequency, stable amplitude of oscillation, varactor-less digitally controlled oscillator (DCO), wide tuning range, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The generation of precise linear frequency modulation is a critical requirement for millimeterwave automotive radars. This paper presents the analysis and design of a CMOS 75.5 - 82.5 GHz monotonically linear digitally controlled oscillator (ML-DCO) fulfilling the requirements of the 77 GHz automotive radar. Non-linear large varactors are avoided. Linear coarse, intermediate, and fine-tuning ranges are achieved by arranging the available minimum Metal-Oxide-Metal (MoM) capacitor in unique configurations. Moreover, a new tuning mechanism derived from a Colpitts topology is discussed to meet the wide tuning requirements without losing linearity. The new arrangement results in a minimal amplitude variation while the ML-DCO is tuned. The coarse, intermediate, and fine-tuning steps from the post-layout simulation are 0.22, 10, and 346 KHz, respectively. The power consumption is 14 mW from a 1.2 V supply. The achieved phase-noise is -98.53 dBc/Hz at a 1 MHz offset when oscillating at 77 GHz. The ML-DCO demonstrates -185 Figure of Merit and -184 Figure of Merit for Tuning.

Published
2019
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2. Positive feedback technique and split‐length transistors for DC‐gain enhancement of two‐stage op‐amps

Author

Seyed Mahmoud Anisheh, Hossein Shamsi, and Mitra Mirhassani

Subjects
positive feedback technique, fully differential two-stage op-amp, split-length transistors, dc-gain enhancement, complementary metal-oxide-semiconductor process, CMOS process, Computer engineering. Computer hardware, TK7885-7895
Abstract

This study presents the design and simulation of a fully differential two‐stage op‐amp in a 0.18 μm complementary metal–oxide–semiconductor process with a 1.8 V supply voltage. In this op‐amp, positive feedback technique and split‐length transistors (SLTs) are employed to increase the DC‐gain of the op‐amp by about 22 dB without affecting the unity‐gain bandwidth (UGBW), stability, power dissipation and output voltage swing of the conventional two‐stage op‐amp. A comprehensive analysis is provided for differential‐mode gain, common‐mode gain, power supply rejection ratio, input‐referred noise, input offset, frequency response and the effect of using SLTs on DC‐gain sensitivity. The proposed op‐amp is utilised in a flip‐around sample‐and‐hold amplifier (SHA). The output spectrum of the SHA shows the total harmonic distortion of 0.0023%. The post‐layout and Monte Carlo simulation results show that the proposed op‐amp has better performance than the state‐of‐the‐art designs.

Published
2017
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49. Design and Evaluation of a Hybrid Chaotic-Bistable Ring PUF

Author

Mohammed A. S. Khalid, Mitra Mirhassani, Madhan Thirumoorthi, and Marko Jovanovic

Subjects
Authentication, Ring (mathematics), Bistability, Computer science, Physical unclonable function, Chaotic, Support vector machine, ComputingMilieux_MANAGEMENTOFCOMPUTINGANDINFORMATIONSYSTEMS, Computer engineering, Hardware and Architecture, Logic gate, Electrical and Electronic Engineering, Field-programmable gate array, Software
Abstract

A physical unclonable function (PUF) is a promising lightweight circuit that provides security and authentication capability for electronic devices with low computational resources. Among various PUFs, the bistable ring PUF (BR-PUF) is considered one of the robust configurations. However, it has been shown that the challenge-response pairs (CRPs) from BR-PUF are vulnerable to statistical machine learning (ML) attacks, such as k-junta learning, support vector machine (SVM), and logistic regression (LR). In this article, we first show that the k-junta attack can break CRPs from the BR-PUF. Then, we present a hybrid chaotic-BR-PUF structure that obfuscates the BR-PUF response with the nonlinearized chaotic response. The proposed PUF structure has been implemented and experimentally evaluated on Xilinx Artix-7 FPGA, and the PUF measurements were captured. The proposed PUF was tested with a powerful statistical method developed using k-junta-based learning to confirm its strength against such attacks and evaluated using CRPs collected. The proposed PUF provides better resistance against ML attacks and reduces the learning accuracy to 50%–60% compared with previously proposed PUFs.

Published
2021
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