Signal acquisition challenges in mobile systems

In recent decades, the advent of mobile computing has changed human lives by providing information that was not available in the past. The mobile computing platform opens a new door to the connected world in which various forms of hand-held and wearable systems are ubiquitous. A single mobile device plays multiple roles and shapes human lives towards a better future. In these systems, sensor-based data acquisition plays an essential role in generating and providing useful information. The increased number of sensors is embedded in a single device in order to process various signal modalities. In practice, more than 30 data converters are required in designing a mobile system in which the data-converting blocks become among the most power-hungry components in battery-operated systems. Due to the increased variety of sensors, mobile systems are meant to face several obstacles. For example, the increased number of sensors increase system power consumption during the system operation. The increased power consumption directly affects operation time because mobile systems are powered by a limited energy source. Moreover, an increased amount of information also gives rise to bandwidth problems in communication due to the increased volume of data transmission. Also, this system design requires a larger area in a silicon die so that multiple signal paths can be placed without cross-channel interference. Therefore, the system design has presented a challenge in terms of trying to resolve the design constraints such as power consumption, bandwidth usage, storage space, and design complexity issues. To overcome these obstacles, in this dissertation, efficient data acquisition and processing methods are investigated. Specifically, this thesis considers the problems of energy-efficient sampling and binary event detection. This dissertation begins by presenting a new signal sampling scheme that enables higher precision signal conversion in compressed-sensing-based signal acquisition. The proposed scheme is based on the popular successive approximation register and employs a modified compressive sensing technique to increase the resolution of successive-approximation-register (SAR) analog-to-digital converter (ADC) architecture. Circuit-level architecture is discussed to implement the proposed scheme using the SAR ADC architecture. A non-uniform quantization scheme is proposed and it improves data quality after data acquisition. The proposed scheme is expected to be used for medium- or high- frequency data conversion. Secondly, the possibility of using fewer ADCs than channels is studied by leveraging sparse-signal representation and blind-source-separation (BSS) techniques. In particular, this dissertation examines the problem of using a single ADC or quantizer system for digitizing multi-channel inputs. Mixing and de-mixing strategies are extensively studied for sampling frequency-sparse signals and the proposed multi-channel architecture can be easily implemented using today's analog/mixed-signal circuits. The third part of this dissertation investigates a binary hypothesis testing problem. In mobile devices such as smartphones and tablet PCs, a major portion of energy is consumed in user interfaces (LCD display and touch input processing). For accurate detection and better user interface, energy-efficient sensing and detection schemes are necessary to manage multiple sensor inputs. A highly efficient detection scheme is presented that can detect binary events reliably with a fraction of the energy consumption required in the conventional energy detection.Electrical and Computer Engineerin

Fully-passive switched-capacitor techniques for high performance SAR ADC design

In recent years, SAR ADC becomes more and more popular in various low-power applications such as wireless sensors and low energy radios due to its circuit simplicity, high power efficiency, and scaling compatibility. However, its speed is limited by its successive approximation procedures and its power efficiency greatly reduces with the ADC resolution going beyond 10 bit. To address these issues, this thesis proposes to embed two techniques: 1) compressive sensing (CS) and 2) noise shaping (NS) to a conventional SAR ADC. The realization of both techniques are based on fully-passive switched-capacitor techniques. CS is a recently emerging sampling paradigm, stating that the sparsity of a signal can be exploited to reduce the ADC sampling rate below the Nyquist rate. Different from conventional CS frameworks which require dedicated analog CS encoders, this thesis proposes a fully-passive CS-SAR ADC architecture which only requires minor modification to a conventional SAR ADC. Two chips are fabricated in a 0.13 µm process to prove the concept. One chip is a single-channel CS-SAR ADC which can reduce the ADC conversion rate by 4 times, thus reducing the ADC power by 4 times. In many wireless sensing applications, multiple ADCs are commonly required to sense multi-channel signals such as multi-lead ECG sensing and parallel neural recording. Therefore, the other chip is a multi-channel CS-SAR ADC which can simultaneously convert 4-channel signals with a sampling rate of one channel’s Nyquist rate. At 0.8 V and 1 MS/s, both chips achieve an effective Walden FoM of around 5 fJ/conversion-step. This thesis also proposes a novel NS SAR ADC architecture that is simple, robust and low power for high-resolution applications. Compared to conventional ∆Σ ADCs, it replaces the power-hungry active integrator with a passive integrator which only requires one switch and two capacitors. Compared to previous 1st-order NS SAR ADC works, it achieves the best NS performance and can be easily extended to 2nd-order. A 1st-order 10-bit NS SAR ADC is fabricated in a 0.13 µm process. Through NS, SNDR increases by 6 dB with OSR doubled, achieving a 12- bit ENOB at OSR = 8. An improved version of a 2nd-order 9-bit NS SAR ADC is designed and simulated in a 40 nm process. The SNDR increases by 10 dB with OSR doubled, achieving a 14-bit ENOB at OSR = 16. At a bandwidth of 312.5 kHz, the Schreier FoM is 181 dB and the Walden FoM is 12.5 fJ/conversion-step, proving that the proposed NS SAR ADC architecture can achieve high resolution and high power efficiency simultaneously.Electrical and Computer Engineerin

Smart Sensor Networks For Sensor-Neural Interface

One in every fifty Americans suffers from paralysis, and approximately 23% of paralysis cases are caused by spinal cord injury. To help the spinal cord injured gain functionality of their paralyzed or lost body parts, a sensor-neural-actuator system is commonly used. The system includes: 1) sensor nodes, 2) a central control unit, 3) the neural-computer interface and 4) actuators. This thesis focuses on a sensor-neural interface and presents the research related to circuits for the sensor-neural interface. In Chapter 2, three sensor designs are discussed, including a compressive sampling image sensor, an optical force sensor and a passive scattering force sensor. Chapter 3 discusses the design of the analog front-end circuit for the wireless sensor network system. A low-noise low-power analog front-end circuit in 0.5μm CMOS technology, a 12-bit 1MS/s successive approximation register (SAR) analog-to-digital converter (ADC) in 0.18μm CMOS process and a 6-bit asynchronous level-crossing ADC realized in 0.18μm CMOS process are presented. Chapter 4 shows the design of a low-power impulse-radio ultra-wide-band (IR-UWB) transceiver (TRx) that operates at a data rate of up to 10Mbps, with a power consumption of 4.9pJ/bit transmitted for the transmitter and 1.12nJ/bit received for the receiver. In Chapter 5, a wireless fully event-driven electrogoniometer is presented. The electrogoniometer is implemented using a pair of ultra-wide band (UWB) wireless smart sensor nodes interfacing with low power 3-axis accelerometers. The two smart sensor nodes are configured into a master node and a slave node, respectively. An experimental scenario data analysis shows higher than 90% reduction of the total data throughput using the proposed fully event-driven electrogoniometer to measure joint angle movements when compared with a synchronous Nyquist-rate sampling system. The main contribution of this thesis includes: 1) the sensor designs that emphasize power efficiency and data throughput efficiency; 2) the fully event-driven wireless sensor network system design that minimizes data throughput and optimizes power consumption

DESIGN AND IMPLEMENTATION OF AN ALL-COTS DIGITAL BACK-END FOR A PULSE-DOPPLER SYNTHETIC APERTURE RADAR

Radar imaging techniques employing synthetic aperture radar (SAR) are ubiquitous in applications such as defense, remote sensing, space exploration, terrain mapping, and many others. However, to obtain fine image resolution, radar systems must be capable of utilizing large signal bandwidths. By the sampling theorem, a large signal bandwidth equates to a high sampling frequency, resulting in more expensive and complex digital electronics required to digitize and process the waveform. Using linear frequency modulated (LFM) pulses and stretch processing techniques, systems such as frequency-modulated continuous-wave (FMCW) radars reduce the required sampling rate at the expense of longer pulses, higher transmit duty cycle, and decreased pulse repetition frequency. While these tradeoffs are often acceptable, in many situations they are not, and a pulse-Doppler radar system is required. These systems can utilize LFM pulses with nearly any desired pulse length and pulse repetition frequency to perform imaging, but they must have an analog-to-digital converter (ADC) and back-end processing capable of handling the full waveform bandwidth, leading to increased cost, size, or both. At the University of Oklahoma’s Advanced Radar Research Center, a pulse-Doppler radar system for use in a SAR application is designed and built using only commercially available components to decrease the size and cost of the radar, specifically the digital back-end. A minimum size and weight is targeted for this system because it is desired to eventually fly the radar and form images on a lightweight airborne platform, such as a quad- or octo-copter. The challenge with using commercial parts for a custom digital pulse-Doppler radar is that it is difficult to meet the strict timing requirements inherent to pulse-Doppler radar while simultaneously meeting the high-bandwidth requirements imposed by SAR. In this thesis, the design and implementation of the digital back-end for the custom SAR system is presented. The focus is placed on designing a control system and clock distribution scheme in the digital back-end to ensure pulse to pulse coherence while maintaining ideal LFM spectral quality. Additionally, a calibration method is devised to provide accurate range measurements each time the radar is turned on even if the latency between the digital transmitter and receiver changes. At the conclusion of this work, it is shown that the radar system is capable of performing accurate pulse-Doppler radar through the generation of range-Doppler maps from data captured by the radar. The results of these tests indicate that the system is suitable for eventual use in SAR imaging applications

Integrated Circuits and Systems for Smart Sensory Applications

Connected intelligent sensing reshapes our society by empowering people with increasing new ways of mutual interactions. As integration technologies keep their scaling roadmap, the horizon of sensory applications is rapidly widening, thanks to myriad light-weight low-power or, in same cases even self-powered, smart devices with high-connectivity capabilities. CMOS integrated circuits technology is the best candidate to supply the required smartness and to pioneer these emerging sensory systems. As a result, new challenges are arising around the design of these integrated circuits and systems for sensory applications in terms of low-power edge computing, power management strategies, low-range wireless communications, integration with sensing devices. In this Special Issue recent advances in application-specific integrated circuits (ASIC) and systems for smart sensory applications in the following five emerging topics: (I) dedicated short-range communications transceivers; (II) digital smart sensors, (III) implantable neural interfaces, (IV) Power Management Strategies in wireless sensor nodes and (V) neuromorphic hardware

Analog Compressive Sensing for Multi-Channel Neural Recording: Modeling and Circuit Level Implementation

RÉSUMÉ Dans cette thèse, nous présentons la conception d’un implant d’enregistrement neuronal multicanaux avec un échantillonnage compressé mis en oeuvre avec un procédé de fabrication CMOS à 65 nm. La réduction de la technologie a˙ecte à la baisse les paramètres des amplificateurs neuronaux couplés en AC, comme la fréquence de coupure basse, en raison de l’e˙et de canal court des transistors MOS. Nous analysons la fréquence de coupure basse et nous constatons que l’origine de ce problème, dans les technologies avancées, est la diminution de l’impédance d’entrée de l’amplificateur opérationnel de transconductance (OTA) en raison de la fuite d’oxyde de grille à l’entrée des OTA. Nous proposons deux solutions pour réduire la fréquence de coupure basse sans augmenter la valeur des condensateurs de rétroaction de l’étage d’entrée. La première solution est appelée rétroaction positive croisée et la deuxième solution utilise des PMOS à oxyde épais dans la paire de l’entrée di˙érentielle de l’OTA. Il est à noter que pour compresser le signal neuronal, nous utilisons le CS dans le domaine analogique. Pour la réalisation, un intégrateur à capacité commutée est requis. Les paramètres non idéaux de l’OTA utilisé dans cet intégrateur, tels que le gain fini, la bande passante, la vitesse de balayage et le changement rapide de la sortie. Toutes ces imperfections induisent des erreurs et réduisent le rapport signal sur bruit (SNR) total. Nous avons simulé ces imperfections sur Matlab et Simulink pour définir les spécifications de l’OTA requis. Aussi, pour concevoir les circuits analogiques correspondant aux interfaces neuronales requises, tels qu’un amplificateur neuronal, une référence de tension compacte et à faible consommation d’énergie est requise. Nous avons proposé une référence de tension de faible consommation d’énergie sans utiliser le transistor bipolaire parasite de la technologie CMOS pour diminuer la surface de silicium requise. Finalement, nous avons complété l’encodeur de CS et un convertisseur analogique-numérique à approximation successive (SAR ADC) requis pour la chaine d’enregistrement des signaux neuronaux dans ce projet.----------ABSTRACT In this thesis we present the design of a multi-channel neural recording implant with analog compressive sensing (CS) in 65 nm process. Scaling down technology demotes the parameters of AC-coupled neural amplifiers, such as increasing the low-cuto˙ frequency due to the short-channel e˙ects of MOS transistors. We analyze the low-cuto˙ frequency and find that the main reason of this problem in advanced technologies is decreasing the input resistance of the operational transconductance amplifier (OTA) due to the gate oxide static current leakage in the input of the OTA. In advanced technologies, the gate oxide is thin and some electrons can penetrate to the channel and cause DC current leakage. We proposed two solutions to reduce the low-cuto˙ frequency without increasing the value of the feedback capacitors of the front-end neural amplifier. The first solution is called cross-coupled positive feedback, and the second solution is utilizing thick-oxide PMOS transistors in the input di˙erential pair of the OTA. Compress the neural signal, we utilized the CS method in analog domain. For its implementation, a switched-capacitor integrator is required. Non-ideal specifications of OTA of CS integrator such as finite gain, bandwidth, slew rate and output swing induce error and reduce the total signal to noise ratio (SNR). We simulated these non-idealities in Matlab and Simulink and extracted the specification of the required OTA. Also, to design analog circuits such as neural amplifier a low power and compact voltage reference is required. We implemented a low-power band-gap reference without utilizing parasitic bipolar transis-tor to decrease the silicon area. At the end, we completed the CS encoder and successive approximation architecture analog-to-digital converter (SAR ADC)

A Closed-Loop Bidirectional Brain-Machine Interface System For Freely Behaving Animals

A brain-machine interface (BMI) creates an artificial pathway between the brain and the external world. The research and applications of BMI have received enormous attention among the scientific community as well as the public in the past decade. However, most research of BMI relies on experiments with tethered or sedated animals, using rack-mount equipment, which significantly restricts the experimental methods and paradigms. Moreover, most research to date has focused on neural signal recording or decoding in an open-loop method. Although the use of a closed-loop, wireless BMI is critical to the success of an extensive range of neuroscience research, it is an approach yet to be widely used, with the electronics design being one of the major bottlenecks. The key goal of this research is to address the design challenges of a closed-loop, bidirectional BMI by providing innovative solutions from the neuron-electronics interface up to the system level. Circuit design innovations have been proposed in the neural recording front-end, the neural feature extraction module, and the neural stimulator. Practical design issues of the bidirectional neural interface, the closed-loop controller and the overall system integration have been carefully studied and discussed.To the best of our knowledge, this work presents the first reported portable system to provide all required hardware for a closed-loop sensorimotor neural interface, the first wireless sensory encoding experiment conducted in freely swimming animals, and the first bidirectional study of the hippocampal field potentials in freely behaving animals from sedation to sleep. This thesis gives a comprehensive survey of bidirectional BMI designs, reviews the key design trade-offs in neural recorders and stimulators, and summarizes neural features and mechanisms for a successful closed-loop operation. The circuit and system design details are presented with bench testing and animal experimental results. The methods, circuit techniques, system topology, and experimental paradigms proposed in this work can be used in a wide range of relevant neurophysiology research and neuroprosthetic development, especially in experiments using freely behaving animals

Floating-Gate Design and Linearization for Reconfigurable Analog Signal Processing

Analog and mixed-signal integrated circuits have found a place in modern electronics design as a viable alternative to digital pre-processing. With metrics that boast high accuracy and low power consumption, analog pre-processing has opened the door to low-power state-monitoring systems when it is utilized in place of a power-hungry digital signal-processing stage. However, the complicated design process required by analog and mixed-signal systems has been a barrier to broader applications. The implementation of floating-gate transistors has begun to pave the way for a more reasonable approach to analog design. Floating-gate technology has widespread use in the digital domain. Analog and mixed-signal use of floating-gate transistors has only become a rising field of study in recent years. Analog floating gates allow for low-power implementation of mixed-signal systems, such as the field-programmable analog array, while simultaneously opening the door to complex signal-processing techniques. The field-programmable analog array, which leverages floating-gate technologies, is demonstrated as a reliable replacement to signal-processing tasks previously only solved by custom design. Living in an analog world demands the constant use and refinement of analog signal processing for the purpose of interfacing with digital systems. This work offers a comprehensive look at utilizing floating-gate transistors as the core element for analog signal-processing tasks. This work demonstrates the floating gate\u27s merit in large reconfigurable array-driven systems and in smaller-scale implementations, such as linearization techniques for oscillators and analog-to-digital converters. A study on analog floating-gate reliability is complemented with a temperature compensation scheme for implementing these systems in ever-changing, realistic environments