Low-power switched capacitor voltage reference

Low-power analog design represents a developing technological trend as it emerges from a rather limited range of applications to a much wider arena affecting mainstream market segments. It especially affects portable electronics with respect to battery life, performance, and physical size. Meanwhile, low-power analog design enables technologies such as sensor networks and RFID. Research opportunities abound to exploit the potential of low power analog design, apply low-power to established fields, and explore new applications. The goal of this effort is to design a low-power reference circuit that delivers an accurate reference with very minimal power consumption. The circuit and device level low-power design techniques are suitable for a wide range of applications. To meet this goal, switched capacitor bandgap architecture was chosen. It is the most suitable for developing a systematic, and groundup, low-power design approach. In addition, the low-power analog cell library developed would facilitate building a more complex low-power system. A low-power switched capacitor bandgap was designed, fabricated, and fully tested. The bandgap generates a stable 0.6-V reference voltage, in both the discrete-time and continuous-time domain. The system was thoroughly tested and individual building blocks were characterized. The reference voltage is temperature stable, with less than a 100 ppm/°C drift, over a --60 dB power supply rejection, and below a 1 [Mu]A total supply current (excluding optional track-and-hold). Besides using it as a voltage reference, potential applications are also described using derivatives of this switched capacitor bandgap, specifically supply supervisory and on-chip thermal regulation

Analog integrated circuit design in ultra-thin oxide CMOS technologies with significant direct tunneling-induced gate current

The ability to do mixed-signal IC design in a CMOS technology has been a driving force for manufacturing personal mobile electronic products such as cellular phones, digital audio players, and personal digital assistants. As CMOS has moved to ultra-thin oxide technologies, where oxide thicknesses are less than 3 nm, this type of design has been threatened by the direct tunneling of carriers though the gate oxide. This type of tunneling, which increases exponentially with decreasing oxide thickness, is a source of MOSFET gate current. Its existence invalidates the simplifying design assumption of infinite gate resistance. Its problems are typically avoided by switching to a high-&kappa/metal gate technology or by including a second thick(er) oxide transistor. Both of these solutions come with undesirable increases in cost due to extra mask and processing steps. Furthermore, digital circuit solutions to the problems created by direct tunneling are available, while analog circuit solutions are not. Therefore, it is desirable that analog circuit solutions exist that allow the design of mixed-signal circuits with ultra-thin oxide MOSFETs. This work presents a methodology that develops these solutions as a less costly alternative to high-&kappa/metal gate technologies or thick(er) oxide transistors. The solutions focus on transistor sizing, DC biasing, and the design of current mirrors and differential amplifiers. They attempt to minimize, balance, and cancel the negative effects of direct tunneling on analog design in traditional (non-high-&kappa/metal gate) ultra-thin oxide CMOS technologies. They require only ultra-thin oxide devices and are investigated in a 65 nm CMOS technology with a nominal VDD of 1 V and a physical oxide thickness of 1.25 nm. A sub-1 V bandgap voltage reference that requires only ultra-thin oxide MOSFETs is presented (TC = 251.0 ppm/°C). It utilizes the developed methodology and illustrates that it is capable of suppressing the negative effects of direct tunneling. Its performance is compared to a thick-oxide voltage reference as a means of demonstrating that ultra-thin oxide MOSFETs can be used to build the analog component of a mixed-signal system

A Low-Power Low-Voltage Bandgap Reference in CMOS

Bandgap reference plays a substantial role in integrated circuit. Traditionally, it provides a constant reference voltage of 1.2051/ for other blocks in the circuit while itself is independent of temperature and power supply. However, the development of CMOS technology has brought us into a new era of high integration and ultra-low power consumption. As the gate length scales down, it is crucial to build circuits that are able to work under a very low voltage power supply, for instance, lower than the bandgap voltage of 1.205V. Building bandgap circuits to generate the conven­ tional bandgap voltage under a low voltage power supply such as 1.2V or IV is no longer practical nor useful. Thus, bandgap references working under low-voltage and consuming low-power is becoming the trend of research and development nowadays. In this thesis work, the potential structure of a low-voltage low-power bandgap reference is proposed, which is based on extracting a current that is a fraction of the traditional bandgap voltage. All the necessary blocks are designed to achieve the high accuracy bandgap reference, including bandgap core circuit, op-amp, start-up circuit and output stage. As a result, the designed bandgap reference is able to work under 1.2V power supply and provides an output reference voltage of 584.7mV. It has a variation of only 244.38fiV for the temperature range of 0°C ~ 125°C and has a variation of only 1.1mV for a power supply range of 1.08V ~ 1.32V. The layout design for the bandgap reference structure is also done carefully at the late stage, with an area of 100fj,m x 85¡xm

NEGATIVE BIAS TEMPERATURE INSTABILITY STUDIES FOR ANALOG SOC CIRCUITS

Negative Bias Temperature Instability (NBTI) is one of the recent reliability issues in sub threshold CMOS circuits. NBTI effect on analog circuits, which require matched device pairs and mismatches, will cause circuit failure. This work is to assess the NBTI effect considering the voltage and the temperature variations. It also provides a working knowledge of NBTI awareness to the circuit design community for reliable design of the SOC analog circuit. There have been numerous studies to date on the NBTI effect to analog circuits. However, other researchers did not study the implication of NBTI stress on analog circuits utilizing bandgap reference circuit. The reliability performance of all matched pair circuits, particularly the bandgap reference, is at the mercy of aging differential. Reliability simulation is mandatory to obtain realistic risk evaluation for circuit design reliability qualification. It is applicable to all circuit aging problems covering both analog and digital. Failure rate varies as a function of voltage and temperature. It is shown that PMOS is the reliabilitysusceptible device and NBTI is the most vital failure mechanism for analog circuit in sub-micrometer CMOS technology. This study provides a complete reliability simulation analysis of the on-die Thermal Sensor and the Digital Analog Converter (DAC) circuits and analyzes the effect of NBTI using reliability simulation tool. In order to check out the robustness of the NBTI-induced SOC circuit design, a bum-in experiment was conducted on the DAC circuits. The NBTI degradation observed in the reliability simulation analysis has given a clue that under a severe stress condition, a massive voltage threshold mismatch of beyond the 2mV limit was recorded. Bum-in experimental result on DAC proves the reliability sensitivity of NBTI to the DAC circuitry

Design of a Programmable Passive SoC for Biomedical Applications Using RFID ISO 15693/NFC5 Interface

Low power, low cost inductively powered passive biotelemetry system involving fully customized RFID/NFC interface base SoC has gained popularity in the last decades. However, most of the SoCs developed are application specific and lacks either on-chip computational or sensor readout capability. In this paper, we present design details of a programmable passive SoC in compliance with ISO 15693/NFC5 standard for biomedical applications. The integrated system consists of a 32-bit microcontroller, a sensor readout circuit, a 12-bit SAR type ADC, 16 kB RAM, 16 kB ROM and other digital peripherals. The design is implemented in a 0.18 μ m CMOS technology and used a die area of 1.52 mm × 3.24 mm. The simulated maximum power consumption of the analog block is 592 μ W. The number of external components required by the SoC is limited to an external memory device, sensors, antenna and some passive components. The external memory device contains the application specific firmware. Based on the application, the firmware can be modified accordingly. The SoC design is suitable for medical implants to measure physiological parameters like temperature, pressure or ECG. As an application example, the authors have proposed a bioimplant to measure arterial blood pressure for patients suffering from Peripheral Artery Disease (PAD)

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

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

Ultra-low power mixed-signal frontend for wearable EEGs

Electronics circuits are ubiquitous in daily life, aided by advancements in the chip design industry, leading to miniaturised solutions for typical day to day problems. One of the critical healthcare areas helped by this advancement in technology is electroencephalography (EEG). EEG is a non-invasive method of tracking a person's brain waves, and a crucial tool in several healthcare contexts, including epilepsy and sleep disorders. Current ambulatory EEG systems still suffer from limitations that affect their usability. Furthermore, many patients admitted to emergency departments (ED) for a neurological disorder like altered mental status or seizures, would remain undiagnosed hours to days after admission, which leads to an elevated rate of death compared to other conditions. Conducting a thorough EEG monitoring in early-stage could prevent further damage to the brain and avoid high mortality. But lack of portability and ease of access results in a long wait time for the prescribed patients. All real signals are analogue in nature, including brainwaves sensed by EEG systems. For converting the EEG signal into digital for further processing, a truly wearable EEG has to have an analogue mixed-signal front-end (AFE). This research aims to define the specifications for building a custom AFE for the EEG recording and use that to review the suitability of the architectures available in the literature. Another critical task is to provide new architectures that can meet the developed specifications for EEG monitoring and can be used in epilepsy diagnosis, sleep monitoring, drowsiness detection and depression study. The thesis starts with a preview on EEG technology and available methods of brainwaves recording. It further expands to design requirements for the AFE, with a discussion about critical issues that need resolving. Three new continuous-time capacitive feedback chopped amplifier designs are proposed. A novel calibration loop for setting the accurate value for a pseudo-resistor, which is a crucial block in the proposed topology, is also discussed. This pseudoresistor calibration loop achieved the resistor variation of under 8.25%. The thesis also presents a new design of a curvature corrected bandgap, as well as a novel DDA based fourth-order Sallen-Key filter. A modified sensor frontend architecture is then proposed, along with a detailed analysis of its implementation. Measurement results of the AFE are finally presented. The AFE consumed a total power of 3.2A (including ADC, amplifier, filter, and current generation circuitry) with the overall integrated input-referred noise of 0.87V-rms in the frequency band of 0.5-50Hz. Measurement results confirmed that only the proposed AFE achieved all defined specifications for the wearable EEG system with the smallest power consumption than state-of-art architectures that meet few but not all specifications. The AFE also achieved a CMRR of 131.62dB, which is higher than any studied architectures.Open Acces