Performance enhancement in the desing of amplifier and amplifier-less circuits in modern CMOS technologies.

In the context of nowadays CMOS technology downscaling and the increasing demand of high performance electronics by industry and consumers, analog design has become a major challenge. On the one hand, beyond others, amplifiers have traditionally been a key cell for many analog systems whose overall performance strongly depends on those of the amplifier. Consequently, still today, achieving high performance amplifiers is essential. On the other hand, due to the increasing difficulty in achieving high performance amplifiers in downscaled modern technologies, a different research line that replaces the amplifier by other more easily achievable cells appears: the so called amplifier-less techniques. This thesis explores and contributes to both philosophies. Specifically, a lowvoltage differential input pair is proposed, with which three multistage amplifiers in the state of art are designed, analysed and tested. Moreover, a structure for the implementation of differential switched capacitor circuits, specially suitable for comparator-based circuits, that features lower distortion and less noise than the classical differential structures is proposed, an, as a proof of concept, implemented in a ΔΣ modulator

A fully on-chip LDO voltage regulator with 37 dB PSRR at 1 MHz for remotely powered biomedical implants

This article presents a fully on-chip low-power LDO voltage regulator dedicated to remotely powered wireless cortical implants. This regulator is stable over the full range of alternating load current and provides fast load regulation achieved by applying a time-domain design methodology. Moreover, a new compensation technique is proposed and implemented to improve PSRR beyond the performance levels which can be obtained using the standard cascode compensation technique. Measurement results show that the regulator has a load regulation of 0.175 V/A, a line regulation of 0.024%, and a PSRR of 37 dB at 1MHz power carrier frequency. The output of the regulator settles within 10-bit accuracy of the nominal voltage (1.8 V) within 1.6μs, at full load transition. The total ground current including the bandgap reference circuit is 28μA and the active chip area measures 290μm×360μm in a 0.18μm CMOS technolog

An accurate, trimless, high PSRR, low-voltage, CMOS bandgap reference IC

Bandgap reference circuits are used in a host of analog, digital, and mixed-signal systems to establish an accurate voltage standard for the entire IC. The accuracy of the bandgap reference voltage under steady-state (dc) and transient (ac) conditions is critical to obtain high system performance. In this work, the impact of process, power-supply, load, and temperature variations and package stresses on the dc and ac accuracy of bandgap reference circuits has been analyzed. Based on this analysis, the a bandgap reference that 1. has high dc accuracy despite process and temperature variations and package stresses, without resorting to expensive trimming or noisy switching schemes, 2. has high dc and ac accuracy despite power-supply variations, without using large off-chip capacitors that increase bill-of-material costs, 3. has high dc and ac accuracy despite load variations, without resorting to error-inducing buffers, 4. is capable of producing a sub-bandgap reference voltage with a low power-supply, to enable it to operate in modern, battery-operated portable applications, 5. utilizes a standard CMOS process, to lower manufacturing costs, and 6. is integrated, to consume less board space has been proposed. The functionality of critical components of the system has been verified through prototypes after which the performance of the complete system has been evaluated by integrating all the individual components on an IC. The proposed CMOS bandgap reference can withstand 5mA of load variations while generating a reference voltage of 890mV that is accurate with respect to temperature to the first order. It exhibits a trimless, dc 3-sigma accuracy performance of 0.84% over a temperature range of -40°C to 125°C and has a worst case ac power-supply ripple rejection (PSRR) performance of 30dB up to 50MHz using 60pF of on-chip capacitance. All the proposed techniques lead to the development of a CMOS bandgap reference that meets the low-cost, high-accuracy demands of state-of-the-art System-on-Chip environments.Ph.D.Committee Chair: Rincon-Mora, Gabriel; Committee Member: Ayazi, Farrokh; Committee Member: Bhatti, Pamela; Committee Member: Leach, W. Marshall; Committee Member: Morley, Thoma

Low-Voltage Analog Circuit Design Using the Adaptively Biased Body-Driven Circuit Technique

The scaling of MOSFET dimensions and power supply voltage, in conjunction with an increase in system- and circuit-level performance requirements, are the most important factors driving the development of new technologies and design techniques for analog and mixed-signal integrated circuits. Though scaling has been a fact of life for analog circuit designers for many years, the approaching 1-V and sub-1-V power supplies, combined with applications that have increasingly divergent technology requirements, means that the analog and mixed-signal IC designs of the future will probably look quite different from those of the past. Foremost among the challenges that analog designers will face in highly scaled technologies are low power supply voltages, which limit dynamic range and even circuit functionality, and ultra-thin gate oxides, which give rise to significant levels of gate leakage current. The goal of this research is to develop novel analog design techniques which are commensurate with the challenges that designers will face in highly scaled CMOS technologies. To that end, a new and unique body-driven design technique called adaptive gate biasing has been developed. Adaptive gate biasing is a method for guaranteeing that MOSFETs in a body-driven simple current mirror, cascode current mirror, or regulated cascode current source are biased in saturation—independent of operating region, temperature, or supply voltage—and is an enabling technology for high-performance, low-voltage analog circuits. To prove the usefulness of the new design technique, a body-driven operational amplifier that heavily leverages adaptive gate biasing has been developed. Fabricated on a 3.3-V/0.35-μm partially depleted silicon-onv-insulator (PD-SOI) CMOS process, which has nMOS and pMOS threshold voltages of 0.65 V and 0.85 V, respectively, the body-driven amplifier displayed an open-loop gain of 88 dB, bandwidth of 9 MHz, and PSRR greater than 50 dB at 1-V power supply

Design and Implementation of a Signal Conditioning Operational Amplifier for a Reflective Object Sensor

Industrial systems often require the acquisition of real-world analog signals for several applications. Various physical phenomena such as displacement, pressure, temperature, light intensity, etc. are measured by sensors, which is a type of transducer, and then converted into a corresponding electrical signal. The electrical signal obtained from the sensor, usually a few tens mV in magnitude, is subsequently conditioned by means of amplification, filtering, range matching, isolation etc., so that the signal can be rendered for further processing and data extraction. This thesis presents the design and implementation of a general purpose op amp used to condition a reflective object sensor’s output. The op amp is used in a non-inverting configuration, as a current-to-voltage converter to transform a phototransistor current into a usable voltage. The op amp has been implemented using CMOS architecture and fabricated in AMI 0.5-µm CMOS process available through MOSIS. The thesis begins with an overview of the various circuits involving op amps used in signal conditioning circuits. Owing to the vast number of applications for sensor signal conditioning circuits, a brief discussion of an industrial sensor circuit is also illustrated. This is followed by the complete design of the op amp and its implementation in the data acquisition circuit. The op amp is then characterized using simulation results. Finally, the test setup and the measurement results are presented. The thesis concludes with an overview of some possible future work on the sensor-op amp data acquisition circuit

Rail-To-Rail Output Op-Amp Design with Negative Miller Capacitance Compensation

In this paper, a two-stage op-amp design is considered using both Miller and negative Miller compensation techniques. The first op-amp design uses Miller compensation around the second amplification stage, whilst the second op-amp design uses negative Miller compensation around the first stage and Miller compensation around the second amplification stage. The aims of this work were to compare the gain and phase margins obtained using the different compensation techniques and identify the ability to choose either compensation technique based on a particular set of design requirements. The two op-amp designs created are based on the same two-stage rail-to-rail output CMOS op-amp architecture where the first stage of the op-amp consists of differential input and cascode circuits, and the second stage is a class AB amplifier. The op-amps have been designed using a 0.35mm CMOS fabrication process

Linearity and Noise Improvement Techniques Employing Low Power in Analog and RF Circuits and Systems

The implementation of highly integrated multi-bands and multi-standards reconfigurable radio transceivers is one of the great challenges in the area of integrated circuit technology today. In addition the rapid market growth and high quality demands that require cheaper and smaller solutions, the technical requirements for the transceiver function of a typical wireless device are considerably multi-dimensional. The major key performance metrics facing RFIC designers are power dissipation, speed, noise, linearity, gain, and efficiency. Beside the difficulty of the circuit design due to the trade-offs and correlations that exist between these parameters, the situation becomes more and more challenging when dealing with multi-standard radio systems on a single chip and applications with different requirements on the radio software and hardware aiming at highly flexible dynamic spectrum access. In this dissertation, different solutions are proposed to improve the linearity, reduce the noise and power consumption in analog and RF circuits and systems. A system level design digital approach is proposed to compensate the harmonic distortion components produced by transmitter circuits’ nonlinearities. The approach relies on polyphase multipath scheme uses digital baseband phase rotation pre-distortion aiming at increasing harmonic cancellation and power consumption reduction over other reported techniques. New low power design techniques to enhance the noise and linearity of the receiver front-end LNA are also presented. The two proposed LNAs are fully differential and have a common-gate capacitive cross-coupled topology. The proposed LNAs avoids the use of bulky inductors that leads to area and cost saving. Prototypes are implemented in IBM 90 nm CMOS technology for the two LNAs. The first LNA covers the frequency range of 100 MHz to 1.77 GHz consuming 2.8 mW from a 2 V supply. Measurements show a gain of 23 dB with a 3-dB bandwidth of 1.76 GHz. The minimum NF is 1.85 dB while the input return loss is greater than 10 dB across the entire band. The second LNA covers the frequency range of 100 MHz to 1.6 GHz. A 6 dBm third-order input intercept point, IIP3, is measured at the maximum gain frequency. The core consumes low power of 1.55 mW using a 1.8 V supply. The measured voltage gain is 15.5 dB with a 3-dB bandwidth of 1.6 GHz. The LNA has a minimum NF of 3 dB across the whole band while achieving an input return loss greater than 12 dB. Finally, A CMOS single supply operational transconductance amplifier (OTA) is reported. It has high power supply rejection capabilities over the entire gain bandwidth (GBW). The OTA is fabricated on the AMI 0.5 um CMOS process. Measurements show power supply rejection ratio (PSRR) of 120 dB till 10 KHz. At 10 MHz, PSRR is 40 dB. The high performance PSRR is achieved using a high impedance current source and two noise reduction techniques. The OTA offers a very low current consumption of 25 uA from a 3.3 V supply