Ultra Low Power Amplification and Digitization System for Neural Signal Recording Applications

The scope is to develop a tunable low power fully integrated bandpass filter and a low power second order sigma-delta ADC modulator for implantable neural signal amplification and digitization applications, with subthreshold circuit design techniques in different CMOS processes. Since biopotentials usually contain low frequency components, the neural filters in this project have to be able to achieve large and predictable time constant for implantable applications. Voltage biased pseudo-resistors are vulnerable to process variations and circuit imperfections, and hence not suitable for implantable applications. A current biased pseudo-resistor is implemented in the neural filters in this work to set the cutoff frequency, and a Taylor series is used to study its linearity. The filters with proposed current biased pseudo-resistors were fabricated in two different CMOS processes and tested. The test results verify that the filters with current biased pseudo-resistors are tunable, and not vulnerable to process variations and circuit imperfections. The filters with current biased pseudo-resistors meet the design requirements of fully integrated, implantable applications. The sigma-delta ADC modulator was designed and simulated in a half micron SOS CMOS process. The simulation results of the ADC confirm the possibility of an ultra low power ADC for neural signal recording applications.School of Electrical & Computer Engineerin

Integrated Circuits for Programming Flash Memories in Portable Applications

Smart devices such as smart grids, smart home devices, etc. are infrastructure systems that connect the world around us more than before. These devices can communicate with each other and help us manage our environment. This concept is called the Internet of Things (IoT). Not many smart nodes exist that are both low-power and programmable. Floating-gate (FG) transistors could be used to create adaptive sensor nodes by providing programmable bias currents. FG transistors are mostly used in digital applications like Flash memories. However, FG transistors can be used in analog applications, too. Unfortunately, due to the expensive infrastructure required for programming these transistors, they have not been economical to be used in portable applications. In this work, we present low-power approaches to programming FG transistors which make them a good candidate to be employed in future wireless sensor nodes and portable systems. First, we focus on the design of low-power circuits which can be used in programming the FG transistors such as high-voltage charge pumps, low-drop-out regulators, and voltage reference cells. Then, to achieve the goal of reducing the power consumption in programmable sensor nodes and reducing the programming infrastructure, we present a method to program FG transistors using negative voltages. We also present charge-pump structures to generate the necessary negative voltages for programming in this new configuration

Information Power Efficiency Tradeoffs in Mixed Signal CMOS Circuits

Increasingly sensors for biological applications are implemented using mixed signal CMOS technologies. As feature sizes in modern technologies decrease with each generation, the power supply voltage also decreases, but the intrinsic noise level increases or remains the same. The performance of any sensor is quantified by the weakest detectable signal, and noise limits the ability of a sensor to detect the signal. In order to explore the trade-offs among incoming signal, the intrinsic physical noise of the circuit, and the available power resources, we apply basic concepts from information theory to CMOS circuits. In this work the circuits are modeled as communication channels with additive colored Gaussian noise and the signal transfer characteristics and noise properties are used to determine the classical Shannon capacity of the system. The waterfilling algorithm is applied to these circuits to obtain the information rate and the bit energy is subsequently calculated. In this dissertation we restricted our attention to operational transconductance amplifiers, a basic building block for many circuits and sensors and oftentimes a major source of noise in a sensor system. It is shown that for typical amplifiers the maximum information rate occurs at bandwidths above the dominant pole of the amplifier where the intrinsic physical circuit noise is diminished, but at the same time the output signal is attenuated. Thus these techniques suggest a methodology for the optimal use of the amplifier, but in many cases it is not practical to use an amplifier in this manner, that is at frequencies above its 3dB cutoff. Further, a direct consequence of applying the classic waterfilling algorithm leads to the idea of using modulation techniques to optimize system performance by shifting signals internally to higher frequencies, providing a practical means to achieve the information rates predicted by waterfilling and at the same time maintaining the real world application of these amplifiers. In addition, the information rates and bit energy for basic CMOS amplifier configurations are studied and compared across configurations and processes. Further the additional design constraints formed by adding the information rate and the bit energy to traditional design characteristics is explored

Power-Efficient and High-Performance Cicruit Techniques for On-Chip Voltage Regulation and Low-Voltage Filtering

This dissertation focuses on two projects. The first one is a power supply rejection (PSR) enhanced with fast settling time (TS) bulk-driven feedforward (BDFF) capacitor-less (CL) low-dropout (LDO) regulator. The second project is a high bandwidth (BW) power adjustable low-voltage (LV) active-RC 4th -order Butterworth low pass filter (LPF). As technology improves, faster and more accurate LDOs with high PSR are going to be required for future on-chip applications and systems.The proposed BDFF CL-LDO will accomplish an improved PSR without degrading TS. This would be achieved by injecting supply noise through the pass device’s bulk terminal in order to cancel the supply noise at the output. The supply injection will be achieved by creating a feedforward path, which compared to feedback paths, that doesn’t degrade stability and therefore allows for faster dynamic performance. A high gain control loop would be used to maintain a high accuracy and dc performance, such as line/load regulation. The proposed CL-LDO will target a PSR better than – 90 dB at low frequencies and – 60 dB at 1 MHz for 50 mA of load current (IvL). The CL-LDO will target a loop gain higher than 90 dB, leading to an improved line and load regulation, and unity-gain frequency (UGF) higher than 20 MHz, which will allow a TS faster than 500 ns. The CL-LDO is going to be fabricated in a CMOS 130 nm technology; consume a quiescent current (IQ) of less than 50 μA; for a dropout voltage of 200 mV and an IvL of 50 mA. As technology scales down, speed and performance requirements increase for on-chip communication systems that reflect the current demand for high speed data-oriented applications. However, in small technologies, it becomes harder to achieve high gain and high speed at the same time because the supply voltage (VvDvD) decreases leaving no room for conventional high gain CMOS structures. The proposed active-RC LPF will accomplish a LV high BW operation that would allow such disadvantages to be overcome. The LPF will be implemented using an active RC structure that allows for the high linearity such communication systems demand. In addition, built-in BW and power configurability would address the demands for increased flexibility usually required in such systems. The proposed LV LPF will target a configurable cut-off frequency (ƒо) of 20/40/80/160 MHz with tuning capabilities and power adjustability for each ƒо. The filter will be fabricated in a CMOS 130 nm technology. The filter characteristics are as following: 4th -order, active-RC, LPF, Butterworth response, VDD = 0.6 V, THD higher than 40 dB and a third-order input intercept point (IIP3) higher than 10 dBm

Advanced CMOS Integrated Circuit Design and Application

The recent development of various application systems and platforms, such as 5G, B5G, 6G, and IoT, is based on the advancement of CMOS integrated circuit (IC) technology that enables them to implement high-performance chipsets. In addition to development in the traditional fields of analog and digital integrated circuits, the development of CMOS IC design and application in high-power and high-frequency operations, which was previously thought to be possible only with compound semiconductor technology, is a core technology that drives rapid industrial development. This book aims to highlight advances in all aspects of CMOS integrated circuit design and applications without discriminating between different operating frequencies, output powers, and the analog/digital domains. Specific topics in the book include: Next-generation CMOS circuit design and application; CMOS RF/microwave/millimeter-wave/terahertz-wave integrated circuits and systems; CMOS integrated circuits specially used for wireless or wired systems and applications such as converters, sensors, interfaces, frequency synthesizers/generators/rectifiers, and so on; Algorithm and signal-processing methods to improve the performance of CMOS circuits and systems

Power-efficient current-mode analog circuits for highly integrated ultra low power wireless transceivers

In this thesis, current-mode low-voltage and low-power techniques have been applied to implement novel analog circuits for zero-IF receiver backend design, focusing on amplification, filtering and detection stages. The structure of the thesis follows a bottom-up scheme: basic techniques at device level for low voltage low power operation are proposed in the first place, followed by novel circuit topologies at cell level, and finally the achievement of new designs at system level. At device level the main contribution of this work is the employment of Floating-Gate (FG) and Quasi-Floating-Gate (QFG) transistors in order to reduce the power consumption. New current-mode basic topologies are proposed at cell level: current mirrors and current conveyors. Different topologies for low-power or high performance operation are shown, being these circuits the base for the system level designs. At system level, novel current-mode amplification, filtering and detection stages using the former mentioned basic cells are proposed. The presented current-mode filter makes use of companding techniques to achieve high dynamic range and very low power consumption with for a very wide tuning range. The amplification stage avoids gain bandwidth product achieving a constant bandwidth for different gain configurations using a non-linear active feedback network, which also makes possible to tune the bandwidth. Finally, the proposed current zero-crossing detector represents a very power efficient mixed signal detector for phase modulations. All these designs contribute to the design of very low power compact Zero-IF wireless receivers. The proposed circuits have been fabricated using a 0.5μm double-poly n-well CMOS technology, and the corresponding measurement results are provided and analyzed to validate their operation. On top of that, theoretical analysis has been done to fully explore the potential of the resulting circuits and systems in the scenario of low-power low-voltage applications.Programa Oficial de Doctorado en Tecnologías de las Comunicaciones (RD 1393/2007)Komunikazioen Teknologietako Doktoretza Programa Ofiziala (ED 1393/2007

Large scale reconfigurable analog system design enabled through floating-gate transistors

This work is concerned with the implementation and implication of non-volatile charge storage on VLSI system design. To that end, the floating-gate pFET (fg-pFET) is considered in the context of large-scale arrays. The programming of the element in an efficient and predictable way is essential to the implementation of these systems, and is thus explored. The overhead of the control circuitry for the fg-pFET, a key scalability issue, is examined. A light-weight, trend-accurate model is absolutely necessary for VLSI system design and simulation, and is also provided. Finally, several reconfigurable and reprogrammable systems that were built are discussed.Ph.D.Committee Chair: Hasler, Paul E.; Committee Member: Anderson, David V.; Committee Member: Ayazi, Farrokh; Committee Member: Degertekin, F. Levent; Committee Member: Hunt, William D