Millimeter-Scale and Energy-Efficient RF Wireless System

This dissertation focuses on energy-efficient RF wireless system with millimeter-scale dimension, expanding the potential use cases of millimeter-scale computing devices. It is challenging to develop RF wireless system in such constrained space. First, millimeter-sized antennae are electrically-small, resulting in low antenna efficiency. Second, their energy source is very limited due to the small battery and/or energy harvester. Third, it is required to eliminate most or all off-chip devices to further reduce system dimension. In this dissertation, these challenges are explored and analyzed, and new methods are proposed to solve them. Three prototype RF systems were implemented for demonstration and verification. The first prototype is a 10 cubic-mm inductive-coupled radio system that can be implanted through a syringe, aimed at healthcare applications with constrained space. The second prototype is a 3x3x3 mm far-field 915MHz radio system with 20-meter NLOS range in indoor environment. The third prototype is a low-power BLE transmitter using 3.5x3.5 mm planar loop antenna, enabling millimeter-scale sensors to connect with ubiquitous IoT BLE-compliant devices. The work presented in this dissertation improves use cases of millimeter-scale computers by presenting new methods for improving energy efficiency of wireless radio system with extremely small dimensions. The impact is significant in the age of IoT when everything will be connected in daily life.PHDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttps://deepblue.lib.umich.edu/bitstream/2027.42/147686/1/yaoshi_1.pd

Image Transmission over Resource-constrained Low-Power Radio Networks

The transmission of large amounts of data over resource-constrained radio frequency (RF) networks is impacted by regulatory constraints and can affect reliability due to channel congestion. These barriers limit the use case to specific applications. This research extends the use case scenario to include the transmission of digital images over such networks which to date has not been widely documented. To achieve this, the overall data volume needs to be reduced to manageable limits. Drawing on previous theoretical work this research explored, developed and implemented novel image compression techniques suitable for use in resource-constrained RF networks. A compression technique was developed which allows variable compression ratios to be selected dependent on the specific use case. This was implemented in an end-to-end low-power radio network operating in license-free spectrum using a customised radio frequency testbed. The robust compression scheme which was developed here enabled out-of-sequence packet reception, further increasing the reliability of the transmission. To allow detailed viewing of a region of interest (ROI) within a large format image (quarter video graphics array) to be transmitted, a novel algorithm was designed and implemented. This enabled the transmission of a region of interest (ROI) in an uncompressed format as a stand-alone image portion, or in combination with a fully compressed image. Significantly, this yielded flexibility in the quantity of data to be transmitted which could increase the lifespan of battery powered devices. A further development allowed direct manipulation of individual image pixels. This permitted additional data, such as battery voltage level to be directly embedded in the transmitted image data. An advantage of this innovative method was that it did not incur any extra overhead in data volume requirements. The embodied system developed is an agnostic image compression algorithm and is suitable for use with resource-constrained devices and networks. Results showed that high compression ratios (70%) with good peak signal-to-noise ratio (PSNR) of approximately 36dB was achievable for a complete end-to-end transmission system

Measurements and characterization of optical wireless communications through biological tissues

Abstract. Radio frequency (RF) has been predominantly utilized for wireless transmission of data across biological tissues. However, RF communications need to address several challenges like interference, safety, security, and privacy, which often hamper the communications through the tissues. To mitigate these challenges, light-based communication can be exploited, as optical wireless communications have unique advantages in terms of security, interference and safety. In this thesis work, we have utilized near-infrared (NIR) light to investigate the feasibility of optical wireless data transfer through biological tissues. To understand the basics of optical communications through biological tissues (OCBT), fresh meat samples and optical phantoms have been used as models of living biological tissues. An experimental testbed containing a data modulated light source and a photodetector was implemented to carry out different measurements regarding the OCBT concept. We have explored the influence of parameters like transmitted optical power, temperature of the tissue, tissue thickness, and position of the light source on the performance of the light-based through-tissue communication system. Analysis of the measurement data allowed us to compare and characterize the effect of used optical elements for better performance evaluation of the optical communication system. We have successfully transmitted a high-resolution image file through a 3 cm thick pork tissue sample. The maximum transmitted power through the tissue sample during the optical communication was 231.4 mW/cm2, which is well below the limits defined by standard of safety regulation. A data rate of 22 kilobits per second has been achieved with the experimental system. Practical limitations of the current testbed prevented obtaining a higher data throughput. The results indicate a dependence of optical received power with respect to the tissue temperature. Moreover, we found both thickness and compositional differences of the biological tissues have a significant impact on the transmittance rate. This thesis work can be considered as a part of the development of 6G technology. The outcomes of this pilot study are very promising, and in the future, numerous potential applications based on OCBT could be developed, including wireless communications to implanted devices, in-body sensors, smart pills, and others

NASA Tech Briefs, July 2012

Topics covered include: Instrument Suite for Vertical Characterization of the Ionosphere-Thermosphere System; Terahertz Radiation Heterodyne Detector Using Two-Dimensional Electron Gas in a GaN Heterostructure; Pattern Recognition Algorithm for High-Sensitivity Odorant Detection in Unknown Environments; Determining Performance Acceptability of Electrochemical Oxygen Sensors; Versatile Controller for Infrared Lamp and Heater Arrays; High-Speed Scanning Interferometer Using CMOS Image Sensor and FPGA Based on Multifrequency Phase-Tracking Detection; Ultra-Low-Power MEMS Selective Gas Sensors; Compact Receiver Front Ends for Submillimeter-Wave Applications; Dynamically Reconfigurable Systolic Array Accelerator; Blocking Losses With a Photon Counter; Motion-Capture-Enabled Software for Gestural Control of 3D Mod; Orbit Software Suite; CoNNeCT Baseband Processor Module Boot Code SoftWare (BCSW); Trajectory Software With Upper Atmosphere Model; ALSSAT Version 6.0; Employing a Grinding Technology to Assess the Microbial Density for Encapsulated Organisms; Demonstration of Minimally Machined Honeycomb Silicon Carbide Mirrors; Polyimide Aerogel Thin Films; Nanoengineered Thermal Materials Based on Carbon Nanotube Array Composites; Composite Laminate With Coefficient of Thermal Expansion Matching D263 Glass; Robust Tensioned Kevlar Suspension Design; Focal Plane Alignment Utilizing Optical CMM; Purifying, Separating, and Concentrating Cells From a Sample Low in Biomass; Virtual Ultrasound Guidance for Inexperienced Operators; Beat-to-Beat Blood Pressure Monitor; Non-Contact Conductivity Measurement for Automated Sample Processing Systems; An MSK Radar Waveform; Telescope Alignment From Sparsely Sampled Wavefront Measurements Over Pupil Subapertures; Method to Remove Particulate Matter from Dusty Gases at Low Pressures; Terahertz Quantum Cascade Laser With Efficient Coupling and Beam Profile; Measurement Via Optical Near-Nulling and Subaperture Stitching; 885-nm Pumped Ceramic Nd:YAG Master Oscillator Power Amplifier Laser System; Airborne Hyperspectral Imaging System; Heat Shield Employing Cured Thermal Protection Material Blocks Bonded in a Large-Cell Honeycomb Matrix; and Asymmetric Supercapacitor for Long-Duration Power Storage

Development and Experimental Analysis of Wireless High Accuracy Ultra-Wideband Localization Systems for Indoor Medical Applications

This dissertation addresses several interesting and relevant problems in the field of wireless technologies applied to medical applications and specifically problems related to ultra-wideband high accuracy localization for use in the operating room. This research is cross disciplinary in nature and fundamentally builds upon microwave engineering, software engineering, systems engineering, and biomedical engineering. A good portion of this work has been published in peer reviewed microwave engineering and biomedical engineering conferences and journals. Wireless technologies in medicine are discussed with focus on ultra-wideband positioning in orthopedic surgical navigation. Characterization of the operating room as a medium for ultra-wideband signal transmission helps define system design requirements. A discussion of the first generation positioning system provides a context for understanding the overall system architecture of the second generation ultra-wideband positioning system outlined in this dissertation. A system-level simulation framework provides a method for rapid prototyping of ultra-wideband positioning systems which takes into account all facets of the system (analog, digital, channel, experimental setup). This provides a robust framework for optimizing overall system design in realistic propagation environments. A practical approach is taken to outline the development of the second generation ultra-wideband positioning system which includes an integrated tag design and real-time dynamic tracking of multiple tags. The tag and receiver designs are outlined as well as receiver-side digital signal processing, system-level design support for multi-tag tracking, and potential error sources observed in dynamic experiments including phase center error, clock jitter and drift, and geometric position dilution of precision. An experimental analysis of the multi-tag positioning system provides insight into overall system performance including the main sources of error. A five base station experiment shows the potential of redundant base stations in improving overall dynamic accuracy. Finally, the system performance in low signal-to-noise ratio and non-line-of-sight environments is analyzed by focusing on receiver-side digitally-implemented ranging algorithms including leading-edge detection and peak detection. These technologies are aimed at use in next-generation medical systems with many applications including surgical navigation, wireless telemetry, medical asset tracking, and in vivo wireless sensors

Small business innovation research: Abstracts of 1984. Phase 1 awards

On September 27, 1984, the National Aeronautics and Space Administration announced the selection of Phase I projects for the Small Business Innovation Research Program. These awards resulted from the evaluation of proposals submitted in response to the 1984 Program Solicitation, SBIR 84-1. In order to make available information on the technical content of the Phase I projects supported by the NASA SBIR Program, the abstracts of those proposals which resulted in awards of contracts are given. In addition, the name and address of the firm performing the work are given for those who may desired additional information about the project. Propulsion, aerodynamics, computer techniques, exobiology and composite materials are among the areas covered

Avaliação ecográfica da morfologia muscular perante situações de sobrecarga agudas e crónicas

Introduction: Ultrasound (US) has an important role in musculoskeletal (MSK) evaluation, allowing the study of muscle morphology and function. Muscle thickness (MT) and muscle echo-intensity (EI) are two important parameters that may quantify muscle structural adaptations to a variety of stimuli. US elastography can also offer semi-quantitative and/or quantitative assessment of tissue stiffness providing relevant information about adaptations of muscle mechanical properties. Purpose: The general aim of the studies presented in this thesis is to explore the potential of quantitative US imaging for assessing the adaptations and responses of the muscle tissue to increased contractile activity using B-mode US and US elastography. The studies were centred on the quadriceps femoris muscle and addressed the study of the effect of strength training and of acute muscle contractile activity on MT, EI and muscle stiffness. Materials and methods: Three different studies were conducted and reported along this thesis. A total of 64 young adults of both genders participated in the studies. The first study (N = 20) evaluated the intra- and inter-session (one week apart) reproducibility of MT and EI parameters and the role of plane of view (transverse vs. longitudinal) and ROI dimension on measurements’ accuracy using the intraclass correlation coefficient [ICC(3,1)], the standard error of measurement (SEM), and the smallest detectable change (SDC). Bland-Altman analysis was used to study the level of agreement between plane views and ROI sizes. The second study (N = 28) investigated the effect of a 15-week strength program on MT and EI in several regions of the heads of the quadriceps femoris. This study included a control group and two training groups performing concentric or eccentric strength training. During this study, changes in vastus lateralis’ (VL) stiffness in response to strength training were evaluated using quasi-static elastography (QSE). In the final study (N = 16), acute changes in VL’s stiffness associated with passive stretching, performance of short but intense contractile activity, and muscle isometric contractions were investigated by means of supersonic shear wave imaging (SSI). Results: Moderate to very high reliability was found for MT (intra-session, ICCs: 0.82- 0.99; inter-session, ICCs: 0.70-0.98) and EI (intra-session, ICCs: 0.74-0.97; inter-session, ICCs: 0.48-0.94). In general, reliability for MT and EI measures was higher in the transverse plane and when using a larger ROI, respectively. Measurements of EI taken with a small versus a large ROI are associated with a small bias and larger limits of Morphological ultrasound evaluation in acute and chronic muscle overloading agreement (LoA). In study 2, 15 weeks of strength training increased MT in the majority but not in all of the scanned regions. Strength training failed in changing EI in most of the quadriceps femoris, excepting in the VI and some regions of the VL. Strength training significantly increased VL’s stiffness. No differences were observed in our quantitative US parameters between concentric and eccentric training. The final study demonstrated an acute increase of around 10% in VL’s shear modulus as a result of performing maximal isometric, concentric, and eccentric contractions. The shear modulus of the VL also increased when the knee moved from 10º to 50º and then to 90º flexion. Finally, a linear relationship between the shear modulus and the level of isometric muscle contraction was observed. Conclusions: Ultrasound measures of MT and EI show moderate to very high reliability. The reliability and agreement of MT and EI measurements are improved in transverse scans and with larger ROIs. QSE could demonstrate an increase in muscle stiffness as a result of strength training. SSI proved to be a good method to investigate muscle mechanical properties changes associated with muscle function. These results emphasise the value of an objective and quantifiable muscle US evaluation for studying muscle adaptation to exercise training and muscle function, in general.Introdução: A ultrassonografia tem um papel importante na avaliação músculoesquelética, permitindo o estudo da morfologia e função muscular. A espessura muscular e a eco- intensidade muscular são dois parâmetros importantes que podem quantificar as adaptações estruturais musculares, quando o musculo é submetido a determinados estímulos. A elastografia por ultrassonografia pode, também, oferecer uma avaliação semi-quantitativa e/ou quantitativa da rigidez do tecido, fornecendo informações relevantes sobre as adaptações das propriedades mecânicas musculares. Objetivo: O objetivo geral, dos estudos apresentados nesta tese, é explorar o potencial da imagem quantitativa ultrassonográfica, de forma a avaliar as adaptações e as respostas do tecido muscular ao aumento da atividade contrátil, usando a elastografia e a ultrassonografia em modo-B. Os estudos foram centrados no músculo do quadricípite femoral e abordaram o estudo do efeito do treino de força e da atividade contrátil muscular na espessura muscular, eco-intensidade e rigidez muscular. Materiais e métodos: Três diferentes estudos foram realizados e descritos ao longo desta tese. Um total de 64 jovens adultos de ambos os géneros participaram dos estudos. No primeiro estudo (N = 20), foi analisada a reprodutibilidade da espessura muscular e da eco-intensidade dos quatro músculos que compõem o quadricípite femoral. Para isso foram adquiridas três imagens em modo B, nos planos longitudinal e transversal, em dois momentos distintos. A eco-intensidade foi medida usando dois tamanhos diferentes de região de interesse, um representado por uma forma retangular, medindo 70 mm2 e um outro representando o máximo do músculo apresentado na imagem ultrassonográfica, evitando as fáscias superficial e profundas do mesmo. A precisão das medidas foi, então, analisada usando o Coeficiente de correlação intra-classe [ICC (3,1)], o erro padrão de medição (SEM) e a menor alteração detectável (SDC). A análise de Bland-Altman foi utilizada para estudar o nível de concordância entre os planos de imagem ultrassonográficos e os diferentes tamanhos da região de interesse. No segundo estudo (N = 28), analisou-se o efeito de um programa de treino de força, com duração de 15 semanas, sobre espessura muscular e ecointensidade em três diferentes regiões de cada um dos quatro músculos que representam o quadricípite femoral: reto femoral, vasto intermédio, vasto medial e vasto lateral. Este estudo incluiu um grupo de controlo e dois grupos de treino, em que um realizou um protocolo de treino concêntrico e o outro de treino excêntrico. Durante este estudo, as alterações na rigidez do vasto lateral, em resposta ao treino de força foram avaliadas usando a elastografia quasi-statica, semi-quantitativa. No último estudo (N = 16), foram analisadas as alterações agudas na rigidez de vasto lateral associadas ao alongamento passivo, ao desempenho de atividade contrátil de curta duração, mas intensa e às contrações isométricas musculares usando a elastografia de onda supersónica por cisalhamento. Resultados: Foi encontrada uma alta ou muito alta reprodutibilidade para espessura muscular (intra-sessão, ICCs: 0,82-0,99; inter-sessão, ICCs: 0,70-0,98) e eco-intensidade (intra-sessão, ICCs: 0,74-0,97; inter-sessão, ICCs: 0,48-0,94). Em geral, a reprodutibilidade para os valores da espessura muscular foi maior no plano transversal e no que diz respeito aos valores da eco-intensidade verificou-se uma melhor reprodutibilidade quando foi utilizada uma região de interesse de maiores dimensões. Um pequeno viés e menores valores de concordância caracterizam as medidas de cointensidade obtidas com uma região de interesse maior ou menor. No estudo 2, os participantes submetidos a 15 semanas de treino de força revelaram o aumento da sua espessura na maioria das regiões musculares avaliadas, mas não em todas. Não foram encontradas alterações significavas dos valores da eco-intensidade com a realização do treino de força na maioria dos músculos do quadricípite femoral, excepto para o vasto intermédio e para algumas regiões do vasto lateral.Por outro lado, o treino de força aumentou significativamente a rigidez do vasto lateral. Não foram observadas diferenças significativas nos parâmetros quantitativos ultrassonográficos entre o treino concêntrico e excêntrico. O último estudo demonstrou um aumento agudo de cerca de10% nos valores da rigidez do vasto lateral como resultado da realização de contrações máximas isométricas, concêntricas e excêntricas. Os valores da rigidez do vasto lateral também aumentaram durante a flexão do joelho de 10º para 50º e posteriormente para 90º. Finalmente, observou-se uma relação linear entre os valores de rigidez do vasto lateral e o nível de contração muscular isométrica do quadricípite femoral. Conclusões: As medidas ultrassonográficas da espessura muscular e eco-intensidade mostram uma reprodutibilidade moderada a muito alta. A reprodutibilidade e a concordância das medidas de espessura muscular e eco-intensidade são maiores no plano transversal e quando é utilizada uma região de interesse de maior dimensão. A elastografia semi-quantitativa mostrou existir um aumento significativo na rigidez muscular como resultado do treino de força. A elastografia por onda de cisalhamento supersónica é um bom método para investigar as alterações das propriedades mecânicas musculares associadas à função muscular. Estes resultados enfatizam a importância de uma avaliação objetiva e quantificável dos músculos por ultrassonografia, para estudar a adaptação muscular ao treino e função muscular, no geral

Digitally-assisted, ultra-low power circuits and systems for medical applications

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2010.Cataloged from PDF version of thesis.Includes bibliographical references (p. 219-225).In recent years, trends in the medical industry have created a growing demand for a variety of implantable medical devices. At the same time, advances in integrated circuits techniques, particularly in CMOS, have opened possibilities for advanced implantable systems that are very small and consume minimal energy. Minimizing the volume of medical implants is important as it allows for less invasive procedures and greater comfort to patients. Minimizing energy consumption is imperative as batteries must last at least a decade without replacement. Two primary functions that consume energy in medical implants are sensor interfaces that collect information from biomedical signals, and radios that allow the implant to communicate with a base-station outside of the body. The general focus of this work was the development of circuits and systems that minimize the size and energy required to carry out these two functions. The first part of this work focuses on laying down the theoretical framework for an ultra-low power radio, including advances to the literature in the area of super-regeneration. The second part includes the design of a transceiver optimized for medical implants, and its implementation in a CMOS process. The final part describes the design of a sensor interface that leverages novel analog and digital techniques to reduce the system's size and improve its functionality. This final part was developed in conjunction with Marcus Yip.by Jose L. Bohorquez.Ph.D