The manufacture and characterisation of microscale magnetic components.

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Design and Optimization of Efficient Wireless Power Transfer Links for Implantable Biotelemetry Systems

Wireless power transmission is a technique that converts energy from radio frequency (RF) electromagnetic (EM) waves into DC voltage, which has been used here for the purpose of providing a power supply to bio–implantable batteryless sensors. The main constraints of the design are to achieve the minimum power required by the application, by still keeping the implant size small enough for the living subject’s body. Resonance–based inductive coupling is a method being actively researched for the use in this type of power transmission, which uses two pairs of inductor coils in the external and implant circuits. In this work, we have employed the resonance–based inductive coupling technique in order to develop a design and optimization procedure for the inductors. We have designed two systems with different configurations, and have achieved power transfer efficiencies of around 80% at a coil distance of 50mm for both systems. We have also optimized the power delivered to the load (implant) and developed a power harvesting unit. Misalignment issues due to the subject’s movements have been modeled for calculating the worst–case alignment, and finite element modeling of the inductors has been performed

High efficiency smart voltage regulating module for green mobile computing

This thesis was submitted for the degree of Doctor of Philosophy and awarded by Brunel University.In this thesis a design for a smart high efficiency voltage regulating module capable of supplying the core of modern microprocessors incorporating dynamic voltage and frequency scaling (DVS) capability is accomplished using a RISC based microcontroller to facilitate all the functions required to control, protect, and supply the core with the required variable operating voltage as set by the DVS management system. Normally voltage regulating modules provide maximum power efficiency at designed peak load, and the efficiency falls off as the load moves towards lesser values. A mathematical model has been derived for the main converter and small signal analysis has been performed in order to determine system operation stability and select a control scheme that would improve converter operation response to transients and not requiring intense computational power to realize. A Simulation model was built using Matlab/Simulink and after experimenting with tuned PID controller and fuzzy logic controllers, a simple fuzzy logic control scheme was selected to control the pulse width modulated converter and several methods were devised to reduce the requirements for computational power making the whole system operation realizable using a low power RISC based microcontroller. The same microcontroller provides circuit adaptations operation in addition to providing protection to load in terms of over voltage and over current protection. A novel circuit technique and operation control scheme enables the designed module to selectively change some of the circuit elements in the main pulse width modulated buck converter so as to improve efficiency over a wider range of loads. In case of very light loads as the case when the device goes into standby, sleep or hibernation mode, a secondary converter starts operating and the main converter stops. The secondary converter adapts a different operation scheme using switched capacitor technique which provides high efficiency at low load currents. A fuzzy logic control scheme was chosen for the main converter for its lighter computational power requirement promoting implementation using ultra low power embedded controllers. Passive and active components were carefully selected to augment operational efficiency. These aspects enabled the designed voltage regulating module to operate with efficiency improvement in off peak load region in the range of 3% to 5%. At low loads as the case when the computer system goes to standby or sleep mode, the efficiency improvent is better than 13% which will have noticeable contribution in extending battery run time thus contributing to lowering the carbon footprint of human consumption

Broadband Impedance Matching of Antenna Radiators

In the design of any antenna radiator, single or multi-element, a significant amount of time and resources is spent on impedance matching. There are broadly two approaches to impedance matching; the first is the distributed impedance matching approach which leads to modifying the antenna geometry itself by identifying appropriate degrees of freedom within the structure. The second option is the lumped element approach to impedance matching. In this approach instead of modifying the antenna geometry a passive network attempts to equalize the impedance mismatch between the source and the antenna load. This thesis introduces a new technique of impedance matching using lumped circuits (passive, lossless) for electrically small (short) non-resonant dipole/monopole antennas. A closed form upper-bound on the achievable transducer gain (and therefore the reflection coefficient) is derived starting with the Bode-Fano criterion. A 5 element equalizer is proposed which can equalize all dipole/monopole like antennas. Simulation and experimental results confirm our hypothesis. The second contribution of this thesis is in the design of broadband, small size, modular arrays (2, 4, 8 or 16 elements) using the distributed approach to impedance matching. The design of arrays comprising a small number of elements cannot follow the infinite array design paradigm. Instead, the central idea is to find a single optimized radiator (unit cell) which if used to build the 2x1, 4x1, 2x2 arrays, etc. (up to a 4x4 array) will provide at least the 2:1 bandwidth with a VSWR of 2:1 and stable directive gain (not greater than 3 dB variation) in each configuration. Simulation and experimental results for a solution to the 2x1, 4x1 and 2x2 array configurations is presented

Simulation and Testing of a High-Temperature Oscillator Circuit

A high-temperature Pierce oscillator circuit was designed, analyzed, simulated, built and tested. The oscillator was designed as part of a high-temperature sensor system for monitoring the condition of equipment operating in harsh environments. The oscillator was designed using a silicon carbide (SiC) metal-oxide-semiconductor field effect transistor (MOSFET) common source amplifier with an LC tank resonant circuit. It was manufactured using gold paste on alumina with 1 mil gold wire bonded between components. All components needed to be capable of operating at temperatures up to 400°C. To this end, high-temperature spiral planar inductors were designed and fabricated. These were found to be within 15% of their designed values. Commercially available high-temperature capacitors, resistors, and MOSFETs were purchased. The oscillator was simulated to determine its output characteristics with temperature varying from room temperature to 350 . This was done by deriving the circuit’s open loop transfer function, which was simulated in both MATLAB and Microcap. These simulations predicted room temperature oscillation frequencies of 3.93 and 3.81MHz respectively. Sensitivity analysis was done on the MATLAB transfer function to predict which components would affect the oscillation frequency the most. Two copies of the oscillator circuit were built and tested. The first produced an oscillation frequency of 3.45MHz at 350°C with an amplitude of 5Vpp­ off of a 5V input, reduced from 7.36Vpp at room temperature. The discrepancy in oscillation frequency compared to simulated values was found to be caused by loading from transmission cables. It was tested further until the MOSFET failed for reasons which are still being investigated. The second copy of the circuit was modified to address cable loading and a small choke in the first and oscillated at 3.68MHz at 100°C with an amplitude of 5.68Vpp for a 5V input, reduced from 6.56Vpp at room temperature. The oscillation frequency of the second oscillator was within 10% of the designed oscillation frequency in both MATLAB and Microcap. Simulations of amplitude change with temperature in the first circuit were all accurate within 5% as well. The second circuit is planned to be tested at higher temperatures and more analysis of the first circuit’s MOSFET failure is planned

Millimeter-Wave Concurrent Dual-Band Sige Bicmos Rfic Phased-Array Transmitter and Components

A concurrent dual-band phased-array transmitter (TX) and its constituent components are studied in this dissertation. The TX and components are designed for the unlicensed bands, 22–29 and 57–64 GHz, using a 0.18-μm BiCMOS technology. Various studies have been done to design the components, which are suitable for the concurrent dual-band phased-array TX. The designed and developed components in this study are an attenuator, switch, phase shifter, power amplifier and power divider. Attenuators play a key role in tailoring main beam and side-lobe patterns in a phased-array TX. To perform the function in the concurrent dual-band phased-array TX, a 22–29 and 57–64 GHz concurrent dual-band attenuator with low phase variations is designed. Signal detection paths are employed at the output of the phased-array TX to monitor the phase and amplitude deviations/errors, which are larger in the high-frequency design. The detected information enables the TX to have an accurate beam tailoring and steering. A 10–67 GHz wide-band attenuator, covering the dual bands, is designed to manipulate the amplitude of the detected signal. New design techniques for an attenuator with a wide attenuation range and improved flatness are proposed. Also, a topology of dual-function circuit, attenuation and switching, is proposed. The switching turns on and off the detection path to minimize the leakages while the path is not used. Switches are used to minimize the number of components in the phased-array transceiver. With the switches, some of the bi-directional components in the transceiver such as an attenuator, phase shifter, filter, and antenna can be shared by the TX and receiver (RX) parts. In this dissertation, a high-isolation switch with a band-pass filtering response is proposed. The band-pass filtering response suppresses the undesired harmonics and intermodulation products of the TX. Phase shifters are used in phased-array TXs to steer the direction of the beam. A 24-GHz phase shifter with low insertion loss variation is designed using a transistor-body-floating technique for our phased-array TX. The low insertion loss variation minimizes the interference in the amplitude control operation (by attenuator or variable gain amplifier) in phased-array systems. BJTs in a BiCMOS process are characterized across dc to 67 GHz. A novel characterization technique, using on-wafer calibration and EM-based de-embedding both, is proposed and its accuracy at high frequencies is verified. The characterized BJT is used in designing the amplifiers in the phased-array TX. A concurrent dual-band power amplifier (PA) centered at 24 and 60 GHz is proposed and designed for the dual-band phased-array TX. Since the PA is operating in the dual frequency bands simultaneously, significant linearity issues occur. To resolve the problems, a study to find significant intermodulation (IM) products, which increase the third intermodulation (IM3) products most, has been done. Also, an advanced simulation and measurement methodology using three fundamental tones is proposed. An 8-way power divider with dual-band frequency response of 22–29 and 57–64 GHz is designed as a constituent component of the phased-array TX

94 GHz Monolithic Transmitter for Weather Radar Application

This thesis was written for concluding my studies at the University of Padua. The main topic is the design of a monolithic transmitter in SiGe bipolar technology, for weather radar application at an operating frequency around 94GHz. At such a high frequency parasitic elements have to be taken into account very carefully. Appropriate matching networks become important to allow the signals to pass across the different ections of the transmitter, without reflections or attenuations. To this aim, transmission lines were used instead of inductors, in order to save size and to have a more reliable modelling of device parameters and parasitic elements. The structure of the transmitter includes a transformer (which acts as Balun), a frequency quadrupler and a buffer. The transmitter input receives a single-ended reference signal at 23.5GHz, with a power of 0dBm on a single-ended input impedance of 50Ω. The output has been designed for a differential load of 100Ω and to operate in the temperature range of 0°C - 100°C, with a typical output power above 10dBm and spurious harmonic below -25dBcopenMotivi di sicurezza e/o proprietà dei risultati e/o informazioni sensibil