Next generation RFID telemetry design for biomedical implants.

The design and development of a Radio Frequency Identification (RFID) based pressure-sensing system to increase the range of current Intra-Ocular Pressure (IOP) sensing systems is described in this dissertation. A large number of current systems use near-field inductive coupling for the transfer of energy and data, which limits the operational range to only a few centimeters and does not allow for continuous monitoring of pressure. Increasing the powering range of the telemetry system will offer the possibility of continuous monitoring since the reader can be attached to a waist belt or put on a night stand when sleeping. The system developed as part of this research operates at Ultra-High Frequencies (UHF) and makes use of the electromagnetic far field to transfer energy and data, which increases the potential range of operation and allows for the use of smaller antennas. The system uses a novel electrically small antenna (ESA) to receive the incident RF signal. A four stage Schottky circuit rectifies and multiplies the received RF signal and provides DC power to a Colpitts oscillator. The oscillator is connected to a pressure sensor and provides an output signal frequency that is proportional to the change in pressure. The system was fabricated using a mature, inexpensive process. The performance of the system compares well with current state of the art, but uses a smaller antenna and a less expensive fabrication process. The system was able to operate over the desired range of 1 m using a half-wave dipole antenna. It was possible to power the system over a range of at least 6.4 cm when the electrically small antenna was used as the receiving antenna

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

Wireless Transceivers for Implantable Microsystems.

In this thesis, we present the first-ever fully integrated mm3 low-power biomedical transceiver with 1 meter of range that is powered by a mm2 thin-film battery. The transceiver is targeted for biomedical implants where size and energy constraints dictated by application make design challenging. Despite all the previous work in RFID tags, form factor of such radios is incompatible with mm3 biomedical implants. The proposed transceiver bridges this gap by providing a compact low-power solution that can run off small thin-film batteries and can be stacked with other system components in a 3D fashion. On the sensor-to-external side, we proposed a novel FSK architecture based on dual-resonator LC oscillators to mitigate unwanted overlap of two FSK tones’ phase noise spectrum. Due to inherent complexity of such systems, fourth order dual-resonator oscillators can exhibit instable operation. We mathematically modeled the instability and derive design conditions for stable oscillations. Through simulation and measurements, validity of derived models was confirmed. Together with other low-power system blocks, the transmitter was successfully implanted in live mouse and in-vivo measurements were performed to confirm successful transmission of vital signals through organic tissue. The integrated transmitter achieved a bit-error-rate of 10-6 at 10cm with 4.7nJ/bit energy consumption. On the external-to-sensor link, we proposed a new protocol to lower receiver peak power, which is highly limited due to small size of mm3 microsystem battery. In the proposed protocol, sending same data multiple times drastically relaxes jitter requirement on the sensor side at the cost of increased power consumption on the external side without increasing peak power radiated by the external unit. The receiver also uses a dual-coil LNA to improve range by 22% with only 11% area overhead. An asynchronous controller manages protocol timing and limits total monitoring current to 43nA. The fabricated receiver consumes 1.6nJ/bit at 40kbps while positioned 1m away from a 2W source.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/102458/1/ghaed_1.pd

Unobtrusive Implementation of Wireless Electronics into Clothing

Research in flexible and stretchable electronics (FSE) has gained significant momentum in recent years due to being mechanically durable without compromising electrical performance. Newer materials and manufacturing methods are studied for efficiently developing FSEs. These materials and methods can be applied to the widespread development of wearable electronics, particularly clothing-integrated electronics. However, seamlessly integrating clothing into electronics has been quite challenging, where achieving an optimal balance between electrical performance and mechanical reliability is a key issue. This thesis aims to find innovative and novel solutions for integrating electronics into clothing, which could be mechanically durable, with limited compromise to their electrical functionality. This thesis combines 3D printing with passive radio frequency identification (RFID) technology to develop wireless platforms integrated into clothing. 3D printing was used to create encapsulants in which electronic components and antennas, designed with conductive yarns and textiles, were embedded. The wireless platforms developed in this study were tested for their mechanical reliability and evaluated for their wireless performance. This study then extended to RFID sensor development, where stimuli responsive materials were 3D printed onto textiles, and wireless performance concerning stimuli response were observed. This study observed that 3D printing encapsulated RFID-based wireless platforms functioned well regarding their wireless performance, despite exposure to moisture and mechanical stress. Although in their preliminary stages, the sensor platforms were also optimally responsive to moisture and temperature changes. Future studies include further evaluating the 3D printing parameters and materials for better mechanical reliability and more extensive studies on the sensor platforms. The wireless platforms developed in this study can be further developed for applications related to health care, logistics, security, and sensing applications

Advances in Supply Chain Management Decision Support Systems: Potential for Improving Decision Support Catalysed by Semantic Interoperability between Systems

Globalization has catapulted ‘cycle time’ as a key indicator of operational efficiency [1] in processes such as supply chain management (SCM). Systems automation holds the promise to augment the ability of supply chain operations or supply networks to rapidly adapt to changes, with minimal human intervention, under ideal conditions. Business communities are emerging as loose federations or organization of networks that may evolve to act as infomediaries in global SCM. These changes, although sluggish, are likely to impact process knowledge and in turn may be stimulated or inhibited by the availability or lack of process interoperability, respectively. The latter will determine operational efficiencies of supply chains. Currently “community of systems” or organization of networks (aligned by industry or business focus) contribute minimally in SCM decisions because true collaboration remains elusive. Convergence and maturity of multiple advances offers the potential for a paradigm shift in interoperability. It may evolve hand-in-hand with [a] the gradual adoption of the semantic web [2] with concomitant development of ontological frameworks, [b] increase in use of multi-agent systems and [c] advent of ubiquitous computing enabling near real-time access to identification of objects and analytics [4]. This paper examines some of these complex trends and related technologies. Irrespective of the characteristics of information systems, the development of various industry-contributed ontologies for knowledge and decision layers, may spur self-organizing networks of business communities and systems to increase their ability to sense and respond, more profitably, through better enterprise and extraprise exchange. In order to transform this vision into reality, systems automation must be weaned from the syntactic web and integrated with the organic growth of the semantic web. Understanding of process semantics and incorporation of intelligent agents with access to ubiquitous near real-time data “bus” are pillars for “intelligent” evolution of decision support systems. Software as infrastructure may integrate plethora of agent colonies through improved architectures (such as, service oriented architecture or SOA) and business communities aligned by industry or service focus may emerge as hubs of such agent empires. However, the feasibility of the path from exciting “pilots” in specific areas toward an informed convergence of systemic real-world implementation remains unclear and fraught with hurdles related to gaps in knowledge transfer from experts in academia to real-world practitioners. The value of interoperability between systems that may catalyse real-time intelligent decision support is further compromised by the lack of clarity of approach and tools. The latter offers significant opportunities for development of tools that may segue to innovative solutions approach. A critical mass of such solutions may spawn the necessary systems architecture for intelligent interoperability, essential for sustainable profitability and productivity in an intensely competitive global economy. This paper addresses some of these issues, tools and solutions that may have broad applicability in several operations including the management of adaptive supply-demand networks [7]

Wireless Power Transfer Techniques for Implantable Medical Devices:A Review

Wireless power transfer (WPT) systems have become increasingly suitable solutions for the electrical powering of advanced multifunctional micro-electronic devices such as those found in current biomedical implants. The design and implementation of high power transfer efficiency WPT systems are, however, challenging. The size of the WPT system, the separation distance between the outside environment and location of the implanted medical device inside the body, the operating frequency and tissue safety due to power dissipation are key parameters to consider in the design of WPT systems. This article provides a systematic review of the wide range of WPT systems that have been investigated over the last two decades to improve overall system performance. The various strategies implemented to transfer wireless power in implantable medical devices (IMDs) were reviewed, which includes capacitive coupling, inductive coupling, magnetic resonance coupling and, more recently, acoustic and optical powering methods. The strengths and limitations of all these techniques are benchmarked against each other and particular emphasis is placed on comparing the implanted receiver size, the WPT distance, power transfer efficiency and tissue safety presented by the resulting systems. Necessary improvements and trends of each WPT techniques are also indicated per specific IMD