High performance CMOS amplifier and phase-locked loop design

Low voltage, high speed and high linearity are three different aspects of the analog circuit performance that designers are trying to achieve. In this dissertation, three design projects targeting these different performance optimizations are introduced.;The first work is a design of a low voltage operational amplifier. In this work, a threshold voltage tuning technique for low voltage CMOS analog circuit design is presented. A 750mV operational amplifier using this technique was designed in a 0.5mum 5V CMOS process with Vtp ≈ -0.9V and Vtn ≈ 0.8V. The active area is 560mum x 760mum. It exhibits a 62dB DC gain and consumes 38muW of power. It works with supply voltages from 0.75V to 1V. Compared to its 5V counterpart consuming the same amount of current, it maintains nearly the same gain bandwidth product of 3.7MHz. This op amp is the FIRST strong inversion op amp that works at a supply voltage below the threshold voltage.;The second is a design of a high speed phase-locked loop for data recovery. A new non-sequential linear phase detector is introduced in this work. Most of the existing phase detectors for data recovery are based on state-machines. The performance of these structures deteriorates rapidly at higher frequencies because of the inadequate settling performance of the flip-flop used to form the state machine. The new phase detector has a speed advantage over the state-machine based designs because it is simple and easy to implement in CMOS technology. Using this phase detector, a PLL was designed in a 0.25mum CMOS process with an active area of 400mum x 290mum. Experimental results show it successfully locks to a 2.1Gbit/s pseudo-random data sequence at 2.3V. It is believed that the architecture is the fastest that has been introduced for data recovery applications.;The third work introduces the design of a highly-linear variable gain amplifier. It achieves high linearity with third harmonic distortion better than -60dB Vopp = 1V at 160MHz in a 0.25mum CMOS process. It has a precise gain step of 6.02dB that is controlled digitally. The linearity performance is achieved with a linearized open loop amplifier configuration. Similar performance could only be achieved using feedback configuration before

Orbiting Geophysical Observatory Attitude Control Subsystem design survey

Development history and design modifications for attitude control subsystem of OG

Systems and Controls Laboratory

Jet spreading in fluid amplifiers, thermal switching of jet flows, and nozzle thrust modulation by vortex generatio

Minimum energy control of a class of electrically driven vehicles

Minimum energy control of class of electrically driven vehicles with application to lunar roving vehicle

올 디지털 클럭 및 데이터 복원 회로를 적용한 고속 광 수신기 설계

학위논문 (박사)-- 서울대학교 대학원 : 전기·컴퓨터공학부, 2016. 8. 정덕균.This thesis presents a 22- to 26.5-Gb/s optical receiver with an all-digital clock and data recovery (ADCDR) fabricated in a 65-nm CMOS process. The receiver consists of an optical front-end and a half-rate bang-bang clock and data recovery circuit. The optical front-end achieves low power consumption by using inverter-based amplifiers and realizes sufficient bandwidth by applying several bandwidth extension techniques. In addition, in order to minimize additional jitter at the front-end, not only magnitude and bandwidth but also phase delay responses are considered. The ADCDR employs an LC quadrature digitally-controlled oscillator (LC-QDCO) to achieve a high phase noise figure-of-merit at tens of gigahertz. The recovered clock jitter is 1.28 psrms and the measured jitter tolerance exceeds the tolerance mask specified in IEEE 802.3ba. The receiver sensitivity is 106 and 184 μApk-pk for a bit error rate of 10−12 at data rates of 25 and 26.5 Gb/s, respectively. The entire receiver chip occupies an active die area of 0.75 mm2 and consumes 254 mW at a data rate of 26.5 Gb/s. The energy efficiencies of the front-end and entire receiver at 26.5 Gb/s are 1.35 and 9.58 pJ/bit, respectively.CHAPTER 1 INTRODUCTION 1 1.1 MOTIVATION 1 1.2 THESIS ORGANIZATION 5 CHAPTER 2 DESIGN OF OPTICAL FRONT-END 7 2.1 OVERVIEW 7 2.2 BACKGROUND ON OPTICAL FRONT-END 9 2.2.1 PHOTODIODE 9 2.2.2 TRANSIMPEDANCE AMPLIFIER 11 2.2.3 POST AMPLIFIER 17 2.2.4 SHUNT INDUCTIVE PEAKING 25 2.3 CIRCUIT IMPLEMENTATION 29 2.3.1 OVERALL ARCHITECTURE 29 2.3.2 TRANSIMPEDANCE AMPLIFIER 31 2.3.3 POST AMPLIFIER 34 2.4 NOISE ANALYSIS 43 2.4.1 PHOTODIODE 43 2.4.2 OPTICAL FRONT-END 44 2.4.3 SENSITIVITY 46 CHAPTER 3 DESIGN OF ADCDR FOR OPTICAL RECEIVER 48 3.1 OVERVIEW 48 3.2 BACKGROUND ON PLL-BASED ADCDR 51 3.2.1 PHASE DETECTOR 51 3.2.2 DIGITAL LOOP FILTER 54 3.2.3 DIGITALLY-CONTROLLED OSCILLATOR 56 3.2.4 ANALYSIS OF BANG-BANG ADCDR 67 3.3 CIRCUIT IMPLEMENTATION 70 3.3.1 OVERALL ARCHITECTURE 70 3.3.2 PHASE DETECTION LOGIC 75 3.3.3 DIGITAL LOOP FILTER 77 3.3.4 LC QUADRATURE DCO 78 CHAPTER 4 EXPERIMENTAL RESULTS 82 CHAPTER 5 CONCLUSION 90 BIBLIOGRAPHY 92 초록 101Docto

An Efficient Supply Modulator for Linear Wideband RF Power Amplifiers

Radio Frequency (RF) Power Amplifiers are responsible for a considerable amount of the power consumption in the entire transmitter-receiver (transceiver) of modern communication systems. The stringent linearity requirements of multi-standard transceivers to minimize cross-talking effects makes Linear Power Amplifiers, particularly class A, the preferred choice in broadband transceivers. This linearity requirement coupled with the fact that the Power Amplifier operates at low transmit power during most of its operation makes the efficiency of the entire transceiver poor. The limited transceiver efficiency leads to a reduction in the battery life of battery operated portable devices like mobile phones; hence drastically limiting talk time. To alleviate this issue, several research groups propose solutions to improve PA power efficiency. However, these solutions usually have a low efficiency at low power and are mostly limited to narrow bandwidth applications. In this thesis, the efficiency of a class A Power amplifier in wideband wireless standards like WiMax is improved by dynamically controlling the bias current and supply voltage of the PA. An efficient supply modulator based on a switching regulator architecture is proposed for controlling the supply voltage. The switching regulator is found to be slew-limited by the bulky inductor and capacitor used to regulate the supply voltage. The proposed solution alleviates the slew rate limitation by adding a bang-bang controlled current source. The proposed supply modulator has an average power efficiency of 81.6 percent and is suitable for wireless standards with bandwidths up to 20MHz compared to the relatively lower efficiencies and bandwidths of state of the art modulators. A class-A PA is shown to promise an average power efficiency of 21.3 percent when the bias current is controlled dynamically and the supply voltage is varied using the proposed supply modulator. This is a significant improvement over the poor average efficiency of 1.06 percent for a fixed bias conventional linear class A PA. The project has been simulated using the TSMC 0.18 micrometer technology

Techniques for Frequency Synthesizer-Based Transmitters.

Internet of Things (IoT) devices are poised to be the largest market for the semiconductor industry. At the heart of a wireless IoT module is the radio and integral to any radio is the transmitter. Transmitters with low power consumption and small area are crucial to the ubiquity of IoT devices. The fairly simple modulation schemes used in IoT systems makes frequency synthesizer-based (also known as PLL-based) transmitters an ideal candidate for these devices. Because of the reduced number of analog blocks and the simple architecture, PLL-based transmitters lend themselves nicely to the highly integrated, low voltage nanometer digital CMOS processes of today. This thesis outlines techniques that not only reduce the power consumption and area, but also significantly improve the performance of PLL-based transmitters.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/113385/1/mammad_1.pd

Circuits and Systems for On-Chip RF Chemical Sensors and RF FDD Duplexers

Integrating RF bio-chemical sensors and RF duplexers helps to reduce cost and area in the current applications. Furthermore, new applications can exist based on the large scale integration of these crucial blocks. This dissertation addresses the integration of RF bio-chemical sensors and RF duplexers by proposing these initiatives. A low power integrated LC-oscillator-based broadband dielectric spectroscopy (BDS) system is presented. The real relative permittivity ε’r is measured as a shift in the oscillator frequency using an on-chip frequency-to-digital converter (FDC). The imaginary relative permittivity ε”r increases the losses of the oscillator tank which mandates a higher dc biasing current to preserve the same oscillation amplitude. An amplitude-locked loop (ALL) is used to fix the amplitude and linearize the relation between the oscillator bias current and ε”r. The proposed BDS system employs a sensing oscillator and a reference oscillator where correlated double sampling (CDS) is used to mitigate the impact of flicker noise, temperature variations and frequency drifts. A prototype is implemented in 0.18 µm CMOS process with total chip area of 6.24 mm^2 to operate in 1-6 GHz range using three dual bands LC oscillators. The achieved standard deviation in the air is 2.1 ppm for frequency reading and 110 ppm for current reading. A tunable integrated electrical balanced duplexer (EBD) is presented as a compact alternative to multiple bulky SAW and BAW duplexers in 3G/4G cellular transceivers. A balancing network creates a replica of the transmitter signal for cancellation at the input of a single-ended low noise amplifier (LNA) to isolate the receive path from the transmitter. The proposed passive EBD is based on a cross-connected transformer topology without the need of any extra balun at the antenna side. The duplexer achieves around 50 dB TX-RX isolation within 1.6-2.2 GHz range up to 22 dBm. The cascaded noise figure of the duplexer and LNA is 6.5 dB, and TX insertion loss (TXIL) of the duplexer is about 3.2 dB. The duplexer and LNA are implemented in 0.18 µm CMOS process and occupy an active area of 0.35 mm^2

RF Power Amplifier and Its Envelope Tracking

This dissertation introduces an agile supply modulator with optimal transient performance for the envelope tracking supply in linear power amplifiers. For this purpose, an on-demand current source module, the bang-bang transient performance enhancer (BBTPE), is proposed. Its objective is to follow fast variations in input signals with reduced overshoot and settling time without deteriorating the steady-state performance of the buck regulator. The proposed approach enables fast system response through the BBTPE and an accurate steady-state output response through a low switching ripple and power efficient dynamic buck regulator. Fast output response with the help of the added module induces a slower rise of inductor current in the buck converter that further assists the proposed system to reduce both overshoot and settling time. To demonstrate the feasibility of the proposed solution, extensive simulations and experimental results from a discrete system are reported. The proposed supply modulator shows 80% improvement in rise time along with 60% reduction in both overshoot and settling time compared to the conventional dynamic buck regulator-based solution. Experimental results for a PA using the LTE 16-QAM 5 MHz standard shows improvement of 7.68 dB and 65.1% in ACPR and EVM, respectively. In a polar power amplifier, the input signal splits into phase and amplitude components using a non-linear conversion operation. This operation broadens the spectrum of the polar signal components. The information of amplitude and phase contains spectral images due to the sampling operation in non-linear conversion operation. These spectral images can be large and cause out-of-band emission in the output spectrum. In addition, during the recombination process of phase and amplitude, a delay mismatch between amplitude and phase signals, which can occur due to separate processing paths of amplitude and phase signals, causes out-of-band emissions, also known as spectral regrowth. This dissertation presents solutions to both of the issues of digital polar power amplifier: spectral images and delay mismatch. In order to reduce the problem of spectral images, interpolation of phase and amplitude is proposed in this work. This increases the effective sampling frequency of the amplitude and phase, which helps to improve the linearity by around 10 dB. In addition, a novel calibration scheme is proposed here for the delay mismatch between phase and amplitude path in a digital polar power amplifier. The scheme significantly reduces the spectral regrowth. The scheme uses the same path for phase and amplitude delay calculation after the recombination that allows having a robust calibration. Furthermore, it can be executed during the empty transmission slots. The proposed scheme is designed in a 40 nm CMOS technology and simulated with a 64-QAM IEEE 802.11n wireless standard. The scheme achieved 7.57 dB enhancement in ACLR and 84.35% improvement in EVM for a 3.5 ns mismatch in phase and amplitude path