Showing posts with label DIGOTA. Show all posts
Showing posts with label DIGOTA. Show all posts

May 30, 2023

[PhD Thesis] Digital-based analog processing in nanoscale CMOS ICs for IoT applications

Digital-based analog processing in nanoscale CMOS ICs for IoT applications
http://hdl.handle.net/10183/249786
PhD Cadndiate: Pedro Filipe Leite Correia De Toledo
Universidade Federal do Rio Grande do Sul. Instituto de Informática
Programa de Pós-Graduação em Microeletrônica.
Advisor: Klimach, Hamilton Duarte
Co-advisor: Crovetti, Paolo Stefano

Abstract: The Internet-of-Things (IoT) concept has been opening up a variety of applications, such as urban and environmental monitoring, smart health, surveillance, and home automation. Most of these IoT applications require more and more power/area efficient Complemen ary Metal–Oxide–Semiconductor (CMOS) systems and faster prototypes (lower time-to market), demanding special modifications in the current IoT design system bottleneck: the analog/RF interfaces. Specially after the 2000s, it is evident that there have been significant improvements in CMOS digital circuits when compared to analog building blocks. Digital circuits have been taking advantage of CMOS technology scaling in terms of speed, power consumption, and cost, while the techniques running behind the analog signal processing are still lagging. To decrease this historical gap, there has been an increasing trend in finding alternative IC design strategies to implement typical analog functions exploiting Digital in-Concept Design Methodologies (DCDM). This idea of re-thinking analog functions in digital terms has shown that Analog ICs blocks can also avail of the feature-size shrinking and energy efficiency of new technologies. This thesis deals with the development of DCDM, demonstrating its compatibility for Ultra-Low-Voltage (ULV) and Power (ULP) IoT applications. This work proves this statement through the proposing of new digital-based analog blocks, such as an Operational Transconductance Amplifiers (OTAs) and an ac-coupled Bio-signal Amplifier (BioAmp). As an initial contribution, for the first time, a silicon demonstration of an embryonic Digital-Based OTA (DB-OTA) published in 2013 is exhibited. The fabricated DB-OTA test chip occupies a compact area of 1,426 µm2 , operating at supply voltages (VDD) down to 300 mV, consuming only 590 pW while driving a capacitive load of 80pF. With a Total Harmonic Distortion (THD) lower than 5% for a 100mV input signal swing, its measured small-signal figure of merit (FOMS) and large-signal figure of merit (FOML) are 2,101 V −1 and 1,070, respectively. To the best of this thesis author’s knowledge, this measured power is the lowest reported to date in OTA literature, and its figures of merit are the best in sub-500mV OTAs reported to date. As the second step, mainly due to the robustness limitation of previous DB-OTA, a novel calibration-free digital-based topology is proposed, named here as Digital OTA (DIG OTA). A 180-nm DIGOTA test chip is also developed exhibiting an area below the 1000 µm2 wall, 2.4nW power under 150pF load, and a minimum VDD of 0.25 V. The proposed DIGOTA is more digital-like compared with DB-OTA since no pseudo-resistor is needed. As the last contribution, the previously proposed DIGOTA is then used as a building block to demonstrate the operation principle of power-efficient ULV and ultra-low area (ULA) fully-differential, digital-based Operational Transconductance Amplifier (OTA), suitable for microscale biosensing applications (BioDIGOTA) such as extreme low area Body Dust. Measured results in 180nm CMOS confirm that the proposed BioDIGOTA can work with a supply voltage down to 400 mV, consuming only 95 nW. The BioDIGOTA layout occupies only 0.022 mm2 of total silicon area, lowering the area by 3.22X times compared to the current state of the art while keeping reasonable system performance, such as 7.6 Noise Efficiency Factor (NEF) with 1.25 µVRMS input-referred noise over a 10 Hz bandwidth, 1.8% of THD, 62 dB of the common-mode rejection ratio (CMRR) and 55 dB of power supply rejection ratio (PSRR). After reviewing the current DCDM trend and all proposed silicon demonstrations, the thesis concludes that, despite the current analog design strategies involved during the analog block development

Fig: a) analog design octagon; b) gm/ID·fT versus the inversion coefficient IC, λc is the parameter corresponding to the fraction of the channel in which the carrier drift velocity reaches the saturated velocity over a portion of the channel geometrical length; c) Performance difference between analog and digital blocks over time; d) Area reduction over the years of the bitcell SRAM, OTA and bandgap reference

Sep 30, 2021

[paper] New Design Concept for the IoT Era

Pedro Toledo, Graduate Student Member, IEEE, Roberto Rubino, Graduate Student Member, IEEE, Francesco Musolino, Member, IEEE, and Paolo Crovetti, Senior Member, IEEE
Re-Thinking Analog Integrated Circuits in Digital Terms: A New Design Concept for the IoT Era
IEEE Transactions on Circuits and Systems—II: Express Briefs, 
Vol. 68, No. 3, March 2021
DOI:  10.1109/TCSII.2021.3049680

* DET, Politecnico di Torino (IT)

Abstract: A steady trend towards the design of mostly-digital and digital-friendly analog circuits, suitable to integration in mainstream nanoscale CMOS by a highly automated design flow, has been observed in the last years to address the requirements of the emerging Internet of Things (IoT) applications. In this context, this tutorial brief presents an overview of concepts and design methodologies that emerged in the last decade, aimed to the implementation of analog circuits like Operational Transconductance Amplifiers, Voltage References and Data Converters by digital circuits. The current design challenges and application scenarios as well as the future perspectives and opportunities in the field of digital-based analog processing are finally discussed.
Fig: a) Kuijk’s Bandgap voltage reference [i]. b) Microcontroller-based proof
of concept prototype.
REF:
[i] K. E. Kuijk, “A precision reference voltage source,” IEEE J. Solid-StateCircuits, vol. SSC-8, no. 3, pp. 222–226, Jun. 1973.