Analyses and design strategies for fundamental enabling building blocks: Dynamic comparators, voltage references and on-die temperature sensors

Dynamic comparators and voltage references are among the most widely used fundamental building blocks for various types of circuits and systems, such as data converters, PLLs, switching regulators, memories, and CPUs. As thermal constraints quickly emerged as a dominant performance limiter, on-die temperature sensors will be critical to the reliable operation of future integrated circuits. This dissertation investigates characteristics of these three enabling circuits and design strategies for improving their performances. One of the most critical specifications of a dynamic comparator is its input referred offset voltage, which is pivotal to achieving overall system performance requirements of many mixed-signal circuits and systems. Unlike offset voltages in other circuits such as amplifiers, the offset voltage in a dynamic comparator is extremely challenging to analyze and predict analytically due to its dependence on transient response and due to internal positive feedback and time-varying operating points in the comparator. In this work, a novel balanced method is proposed to facilitate the evaluation of time-varying operating points of transistors in a dynamic comparator. Two types of offsets are studied in the model: (1) static offset voltage caused by mismatches in mobilities, transistor sizes, and threshold voltages, and (2) dynamic offset voltage caused by mismatches in parasitic capacitors or loading capacitors. To validate the proposed method, dynamic comparators in two prevalent topologies are implemented in 0.25 μm and 40 nm CMOS technologies. Agreement between predicted results and simulated results verifies the effectiveness of the proposed method. The new method and the analytical models enable designers to identify the most dominant contributors to offset and to optimize the dynamic comparators\u27 performances. As an illustrating example, the Lewis-Gray dynamic comparator was analyzed using the balanced method and redesigned to minimize its offset voltage. Simulation results show that the offset voltage was easily reduced by 41% while maintaining the same silicon area. A bandgap voltage reference is one of the core functional blocks in both analog and digital systems. Despite the reported improvements in performance of voltage references, little attention has been focused on theoretical characterizations of non-ideal effects on the value of the output voltage, on the inflection point location and on the curvature of the reference voltage. In this work, a systematic approach is proposed to analytically determine the effects of two non-ideal elements: the temperature dependent gain-determining resistors and the amplifier offset voltage. The effectiveness of the analytical models is validated by comparing analytical results against Spectre simulation results. Research on on-die temperature sensor design has received rapidly increasing attention since component and power density induced thermal stress has become a critical factor in the reliable operation of integrated circuits. For effective power and thermal management of future multi-core systems, hundreds of sensors with sufficient accuracy, small area and low power are required on a single chip. This work introduces a new family of highly linear on chip temperature sensors. The proposed family of temperature sensors expresses CMOS threshold voltage as an output. The sensor output is independent of power supply voltage and independent of mobility values. It can achieve very high temperature linearity, with maximum nonlinearity around +/- 0.05oC over a temperature range of -20oC to 100oC. A sizing strategy based on combined analytical analysis and numerical optimization has been presented. Following this method, three circuits A, B and C have been designed in standard 0.18 ym CMOS technology, all achieving excellent linearity as demonstrated by Cadence Spectre simulations. Circuits B and C are the modified versions of circuit A, and have improved performance at the worst corner-low voltage supply and high threshold voltage corner. Finally, a direct temperature-to-digital converter architecture is proposed as a master-slave hybrid temperature-to-digital converter. It does not require any traditional constant reference voltage or reference current, it does not attempt to make any node voltage or branch current constant or precisely linear to temperature, yet it generates a digital output code that is very linear with temperature

Bandgap Reference Design at the 14-Nanometer FinFET Node

As supply voltages continue to decrease, it becomes harder to ensure that the voltage drop across a diode-connected BJT is sufficient to conduct current without sacrificing die area. One such solution to this potential problem is the diode-connected MOSFET operating in weak inversion. In addition to conducting appreciable current at voltages significantly lower than the power supply, the diode-connected MOSFET reduces the total area for the bandgap implementation. Reference voltage variations across Monte Carlo perturbations are more pronounced as the variation of process parameters are exponentially affected in subthreshold conduction. In order for this proposed solution to be feasible, a design methodology was introduced to mitigate the effects of process variation. A 14 nm bandgap reference was created and simulated across Monte Carlo perturbations for 100 runs at nominal supply voltage and 10% variation of the power supply in either direction. The best case reference voltage was found and used to verify the proposed resistive network solution. The average temperature coefficient was measured to be 66.46 ppm/◦C and the voltage adjustment range was found to be 204.1 mV. The two FinFET subthreshold diodes consume approximately 2.8% of the area of the BJT diode equivalent. Utilizing an appropriate process control technique, subthreshold bandgap references have the potential to overtake traditional BJT-based bandgap architectures in low-power, limited-area applications

A low-power native NMOS-based bandgap reference operating from −55°C to 125°C with Li-Ion battery compatibility

Summary The paper describes the implementation of a bandgap reference based on native-MOSFET transistors for low-power sensor node applications. The circuit can operate from −55°C to 125°C and with a supply voltage ranging from 1.5 to 4.2 V. Therefore, it is compatible with the temperature range of automotive and military-aerospace applications, and for direct Li-Ion battery attach. Moreover, the circuit can operate without any dedicated start-up circuit, thanks to its inherent single operating point. A mathematical model of the reference circuit is presented, allowing simple portability across technology nodes, with current consumption and silicon area as design parameters. Implemented in a 55-nm CMOS technology, the voltage reference achieves a measured average (maximum) temperature coefficient of 28 ppm/°C (43 ppm/°C) and a measured sample-to-sample variation within 57 mV, with a current consumption of 420 nA at 27°C

Advanced Electrical Characterization of Oxide TFTs Design of a Temperature Compensated Voltage Reference

Any electronic device, regardless of its function, needs a reference voltage source that feeds reliably, i.e., which generates a constant voltage, upstream and regardless of external environmental conditions, such as temperature. Since such a characteristic negatively influences the behavior of the devices, whose base elements are transistors, it is essential to design a circuit that provides a voltage which is invariant over a temperature range. In this work is designed a circuit that is responsible for generating a reference voltage using only thin film transistors or TFTs, on glass substrate. However, in order to validate the concept used in the mentioned transistors, it is also dimensioned and simulated the proposed circuit in 130 nm CMOS technology, where the respective results are expected to be comparative between the two technologies. For CMOS technology, for a nominal reference voltage of 124,0 mV, Cadence simulation reveals ±2,2 ppm/ºC temperature coefficient, between -20 °C and 100 °C. The power consumptions are and 1,434 mW and 4,566 mW for both CMOS and IGZO-TFT technologies, respectively

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

Temperature sensors in SOI CMOS for high temperature applications

Ph.DDOCTOR OF PHILOSOPH

Power Management Circuits for Front-End ASICs Employed in High Energy Physics Applications

The instrumentation of radiation detectors for high energy physics calls for the development of very low-noise application-specific integrated-circuits and demanding system-level design strategies, with a particular focus on the minimisation of inter-ference noise from power anagement circuitry. On the other hand, the aggressive pixelisation of sensors and associated front-end electronics, and the high radiation exposure at the innermost tracking and vertex detectors, requires radiation-aware design and radiation-tolerant deep sub-micron CMOS technologies. This thesis explores circuit design techniques towards radiation tolerant power management integrated circuits, targeting applications on particle detectors and monitoring of accelerator-based experiments, aerospace and nuclear applications. It addresses advantages and caveats of commonly used radiation-hard layout techniques, which often employ Enclosed Layout or H-shaped transistors, in respect to the use of linear transistors. Radiation tolerant designs for bandgap circuits are discussed, and two different topologies were explored. A low quiescent current bandgap for sub-1 V CMOS circuits is proposed, where the use of diode-connected MOSFETs in weak-inversion is explored in order to increase its radiation tolerance. An any-load stable LDO architecture is proposed, and three versions of the design using different layout techniques were implemented and characterised. In addition, a switched DC-DC Buck converter is also studied. For reasons concerning testability and silicon area, the controller of the Buck converter is on-chip, while the inductance and the power transistors are left on-board. A prototype test chip with power management IP blocks was fabricated, using a TSMC 65 nm CMOS technology. The chip features Linear, ELT and H-shape LDO designs, bandgap circuits and a Buck DC-DC converter. We discuss the design, layout and test results of the prototype. The specifications in terms of voltage range and output current capability are based on the requirements set for the integrated on-detector electronics of the new CGEM-IT tracker for the BESIII detector. The thesis discusses the fundamental aspects of the proposed on-detector electronics and provides an in-depth depiction of the front-end design for the readout ASIC