Faculty Publications
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Item Common mode feedback circuits for low voltage fully-differential amplifiers(World Scientific Publishing Co. Pte Ltd wspc@wspc.com.sg, 2016) Rekha, S.; Laxminidhi, T.Continuous time common mode feedback (CMFB) circuits for low voltage, low power applications are proposed. Four circuits are proposed for gate/bulk-driven pseudo-differential transconductors operating on sub-1-V power supply. The circuits are validated for a bulk-driven pseudo-differential transconductor operating on 0.5V in 0.18?m standard CMOS technology. Simulation results reveal that the proposed CMFB circuits offer power efficient solution for setting the output common mode of the transconductors. They also load the transconductor capacitively offering capacitance of about 1fF to tens of femto farads. © 2016 World Scientific Publishing Company.Item Ultra-low voltage, power efficient continuoustime filters in 180 nm CMOS technology(Institution of Engineering and Technology kvukmirovic@theiet.org, 2019) Rekha, S.; Vasantha, V.M.; Laxminidhi, T.The authors propose circuit techniques to implement integrated continuous-time filters for low voltage and low power applications. A fourth order Gm-C filter and a fifth order active-RC Chebyshev filter are used as test vehicles to validate the ideas. Basic building blocks are bulk driven transconductors. Gm-C filter and active-RC filter offer bandwidth of 1 MHz and 750 kHz, respectively while exhibiting a good figure of merit thus ensuring that the designs are energy efficient. Both the filters, fabricated on the same chip in 180 nm CMOS technology, operate on 0.5 V power supply. They offer a dynamic range of 45 and 46.6 dB, respectively. © The Institution of Engineering and Technology 2019.Item A 1.8 V 8.62 µW Inverter-based Gain-boosted OTA with 109.3 dB dc Gain for SC Circuits(Taylor and Francis Ltd, 2019) Kaliyath, Y.; Laxminidhi, T.This paper presents a low-power inverter-based gain-boosted operational transconductance amplifier (OTA) for switched capacitor (SC) circuits operating at higher supply voltage (>1 V). The proposed OTA is implemented using UMC 180 nm CMOS technology with a supply voltage of 1.8 V and it offers a high dc gain with a unity gain bandwidth (UGB) suitable for audio applications. All the transistors of the proposed OTA are operated in sub-threshold region to minimize the power consumption. Gain-boosting technique is employed to achieve a higher dc gain. The post-layout simulations demonstrate the robust performance of the proposed OTA, which delivers a high dc gain of 109.3 dB and a UGB of 5.29 MHz at 81° phase margin (PM) with a capacitive load of 2.5 pF for a typical process corner at room temperature (27°C). The proposed OTA draws a quiescent current ((Formula presented.)) of 4.79 µA, resulting in a power consumption of 8.62 µW. © 2019, © 2019 IETE.Item Low Power, High Speed, Inductor-less Cascaded Charge Pump Phase Locked Loop(Birkhauser, 2025) Kirankumar, H.L.; Rekha, S.; Laxminidhi, T.A wide frequency range, inductor-less, charge pump phase locked loop (CP-PLL) is presented in this paper. It has a multi-phase, two stage cascaded architecture. This design uses a dead-zone free, zero blind-zone phase frequency detector (PFD) and a low mismatch charge pump (CP) circuit to generate low jitter clocks. A 3-stage single ended ring oscillator of 625 MHz VCO is designed for the first stage. An 8-phase feed-forward coupled VCO with programmable multi band ranging from 1.25 to 5 GHz is designed for the second stage of this cascaded system. Overall, this proposed cascaded PLL achieves jitter FOM and jitter-N FOM of -227.1 and ? 250.1 dB, respectively for 5 GHz output frequency with 1.44 ps rms jitter while consuming 9.24 mW of power from 1.2 V supply. This proposed clock generator circuit, designed in UMC 65 nm CMOS technology, occupies an area of 0.079 mm2. This study contributes to the development of energy-efficient, high speed clock generation solutions derived from a low reference clock. © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2025.