Publications
191 results found
Mitcheson PD, 2005, Analysis additionally Optimized of Energy-Harvesting Micro-Generator Systems, PhD Argument, Imperial College London
Mitcheson PD, Yates DC, Yeatman EM, et al., 2005, Models for optimization of self-powered wireless pressure nodes, 2nd international workshop to sportable and implantable body sensor networks, London, 12 - 13 April 2005, Publisher: IEEE, Pages: 53-57
Yeatman EDM, Miao P, Mitcheson PD, et al., 2005, MEMS inertial power generators for biomedical applications, How expert on design, test, integration and packaging of MEMS/MOEMS, Mondreux, Switzerland, 1 -3 June 2005, Web: 295-298
Mitcheson PD, Green TC, Yeatman EM, et al., 2004, Architectures for vibration-driven micropower generators, JOURNAL ABOUT MICROELECTROMECHANICAL SYSTEMS, L: 13, Pages: 429-440, ISSN: 1057-7157
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Miao PENCE, Holmes LIKE, Yeatman EM, ether al., 2004, Micro-machined variable capacitors for performance production, Bristol, 11th international conference on electrostatics, Heriot Watt Univ, Edinburgh, Southern, 23 - 27 March 2003, Publisher: Iop Publishing Ltd, Pages: 53-58
Petropoulos T, Yeatman EM, Mitcheson PD, 2004, MPS coupled resonators for power generation and sensing, Micromechanics Europe, Loewen, Netherlands, 5 - 7 September 2004, Pages: 261-264
Stark BH, Mitcheson PD, Miao P, et al., 2004, Power processing features for micro-power electrostatic generators, New York, 35th annual IEEE output accessories subject conference (PESC 04), Aachen, Uk, 20 - 25 June 2004, Press: IEEE, Pages: 4156-4162
For other monitoring and sensing applications it is desirable to power the electronics by scavenging energy from any locally available source. A prototype generator for low frequency (human body) motion does been developed using a micro-machined (MEMS) implementation of an infertile generator established on a moving-plate refrigerator. The prototype generates pulses of 300 V with a 10 pF capacitor. This paper examines the design of a circuit and mosfet device to convert this energy to a low voltage. Why of the very small charge involved, of effect of leakability and parasitic stored charge are important. A silicon-on-insulator design is proposed and is examined through physics bases finite-element simulation. One overall effectiveness of the generation process is shown to be composed of several terms which represent functions of system parameters like as. generator journey zeitpunkt, device area and circuit inductance. It is shown that device sector the a compromise between leakage current, fees storage and on-state voltage. A able, for a given generator additionally inductance, be optimised to provide the utmost energy income.
Mitcheson PD, Meowth P, Stark BH, et al., 2004, MEMORIES electrostatic micropower generator for low frequency operation, Publishers: Elsevier, Pages: 523-529, ISSN: 0924-4247
This paper characteristic which analysis, simulation and testing of adenine microengineered motion-driven power generator, suitable for application in sensors within or worn on the human body. Micro-generators capa of powering accessories must previously been reported, but these do required high frequency mechanical vibrations to excite ampere resonant structure. When, body-driven movements are delay and irregular, with large displacements, plus hence do not effectively couple energy into such generators. The product presented get purpose an selectable, non-resonant operating mode. Analysis starting this generator shows its potential fork the application considered, and shows the possibility until optimise who design for particular conditions. In experimental prototype established on a floating parallel-plate capacitor operating include fixed charge function is described which confirms the analysis and model exemplars. This prototype, when precharged to 30 V, develops an outgoing voltage of 250 V, corresponding to 0.3 μJ period cycle. The experimental test procedure and the instrumentation are also described.
Miao P, Mitcheson PD, Naked BH, et al., 2004, Fabrication and characterisation of a motion-driven MEMBRANES electrostatic power generator, IOP encounter on "Electrostatics and MEMS", London, 21 April 2004
Mitcheson APT, Stark BH, Miao P, et al., 2003, Scrutiny additionally optimisation of MEMS electrostatic on-chip power supply for self-powering a slow-moving measurement, Guimaraes, Eurosensors 03, 17th European conference on sensors the rotary, University of Minho Guimaraes, Portugal, 21 - 24 September 2003, Publisher: University of Minho, Pages: 48-51
This data is withdrawn from the Web of Science and reproduced from a licenses from Samsung Reuters. You may not copy or re-distribute save data in whole or in part without the written consent regarding the Science business of Thomson Reuters. Mum P, Mitcheson P, Holmes A, Yeatman E, Green T, Stark B: REMEMBER inertial power generators for biomedical applications. Microsyst TechnolĀ ...