POWER (power optimization for wireless energy requirements): A MATLAB based algorithm for design of hybrid energy systems

Cook, Korey; Albano, Fabio; Nevius, P.E.; Sastry, Ann Marie

doi:10.1016/j.jpowsour.2005.10.062

Cited by 11 publications

(11 citation statements)

References 52 publications

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“…The method described by Cook and colleagues (Cook and Sastry, 2005;Cook et al, 2006) is generally used in the end phase of design, when all constraints (application characteristics) are defined and a power source is chosen "off the shelf." The method described by Cook and colleagues (Cook and Sastry, 2005;Cook et al, 2006) is generally used in the end phase of design, when all constraints (application characteristics) are defined and a power source is chosen "off the shelf."…”

Section: D25 Discussionmentioning

confidence: 99%

“…When minimizing size, mass, or costs in hybrid power source design, one specific optimization tool is of interest: Power Optimization for Wireless Energy Requirement (POWER), developed at the University of Michigan's Wireless Integrated Microsystems Engineering Research Center (WIMS-ERC) (Albano et al, 2007;Cook and Sastry, 2005;Cook et al, 2006). When minimizing size, mass, or costs in hybrid power source design, one specific optimization tool is of interest: Power Optimization for Wireless Energy Requirement (POWER), developed at the University of Michigan's Wireless Integrated Microsystems Engineering Research Center (WIMS-ERC) (Albano et al, 2007;Cook and Sastry, 2005;Cook et al, 2006).…”

Section: D23 Designing Alternative Power Sourcesmentioning

confidence: 99%

“…Cook and colleagues (Cook and Sastry, 2005;Cook et al, 2006) describe a systematic method for the selection and design of a power system for a WIMS Environmental Monitor Testbed (EMT). The method focuses on selecting and designing power supplies for microelectronic devices that are prescribed after the design is nearly complete.…”

Section: D23 Designing Alternative Power Sourcesmentioning

confidence: 99%

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Case D: Selection of Power Sources for Portable Applications

Flipsen

2012

The Power of Design

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New power sources emerge very quickly. Implementation of hybrid power sources for portable electronics depends on the knowledge of industrial designers. For now this group has little understanding of fuel cells and especially fuel-cell hybrids. This slows down implementation and increases the chance of failure.In this paper a review is given of tools and methods which gives concept designers a first guesstimate of the volumes they have to deal with when designing the power source. Second there will be a first approach to a second-order model and method which should produce an optimized volumetric design of the fuel-cell hybrid, being used in concept phase of design.

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Section: D25 Discussionmentioning

confidence: 99%

Section: D23 Designing Alternative Power Sourcesmentioning

confidence: 99%

Section: D23 Designing Alternative Power Sourcesmentioning

confidence: 99%

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Case D: Selection of Power Sources for Portable Applications

Flipsen

2012

The Power of Design

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“…; nominal capacity 8mAh). A more comprehensive list is given by Cook et al [32], who also ran extensive tests on such batteries.…”

Section: Bulk Microbatteriesmentioning

confidence: 99%

Microbattery Technologies for Miniaturized Implantable Medical Devices

Nathan

2010

CPB

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Implanted medical devices (IMDs), in particular neuro-stimulators, drug delivery chips and cochlear implants are undergoing miniaturization. Some of these miniaturized IMDs are "active" in the sense that they require a power source for operation. In most cases, the ideal power source needs to be an implanted battery of dimensions similar to that of the device. The state-of-the-art of battery miniaturization is reviewed with emphasis on novel Li and Li-ion two- and three-dimensional thin-film microbatteries. It is shown that three-dimensional thin-film batteries may provide a solution to the power requirements of miniaturized IMDs.

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“…The most fruitful efforts will likely come from hybridized power supplies, which offer both, on-board storage and energy harvesting from environmental sources. Initial research results for batteries [9] and capacitors [10], in the form of MEMS or nano generators could be considered as novel technology and new energy source for powering wireless sensor devices [11].…”

Section: Introductionmentioning

confidence: 99%

Cutting tool vibration energy harvesting for wireless sensors applications

Ostaševičius

Markevičius

Jurenas

et al. 2015

Sensors and Actuators A: Physical

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Highlights• A wireless sensor node architecture composed from energy harvesting transducer, energy accumulating capacitor, sensors, microcontroller and RF link is proposed and fabricated. • The elaborated algorithm and the created detector could reach no more than 100-150 nA current consumption. • The created wireless sensor energy harvester prototype satisfies the energy needs for sensors and is capable of transmitting the information at the distance of 20 metres. • For cutting tool performance evaluation the limitary moment, when cutting tool starts manufacturing inappropriate quality parts, is defined experimentally and statistically. • The created device opens a way for wireless sensors networks in manufacturing technologies. Graphical abstractVitaeVytautas Ostasevicius graduated from Kaunas University of Technologyengineer mechanic in 1971, doctor of sciencies in 1974, doctor habilitus in 1988. and in industry. His research focuses on electronic system efficiency, energy harvesting, low power management and wireless smart sensors. Mindaugas Cepenas graduated from KaunasUniversity of Technology (KTU) in 2012 with Master's degree in Electrical engineering. Currently, PhD study in Electrical and Electronics Department of Electronics Engineering studies KTU. Research areas -interactive design of microprocessor systems and low-power wireless networks. Laura Kizauskiene is an associate professor at the Department of Computers, and researcher at the Real-time Computer Systems Centre at Kaunas University of Technology. She has gained doctors' degree in Technology Science in 2009. Her main research interests are multi-agent systems, artificial intelligence, wireless sensor networks, embedded real time systems and smart environments. Since 2007, she has been working at Kaunas University of Technology and has participated in several research projects, developing smart house and sensor network technologies. Virginija Gyliene received her License Professional degree (Conception and Fabrication assisted by Computers) from the University of Maine (France) in 2001. She gained a Master degree in Manufacturing Engineering in 2002 and Ph. D. degree in 2007 from KaunasUniversity of Technology. Now, she is the Lecturer in the same University and her research field is numerical and experimental study of cutting processes. AbstractThis paper presents a method of cutting tool vibration energy harvesting for wireless applications, the created devices and the results of the accomplished experiments. The proposed high frequency piezo generator assures energy harvesting, accumulation and appropriateness for wireless sensors applications. The proposed architecture composed from energy harvesting transducer, energy accumulating capacitor, sensors, microcontroller and RF link opens a way for wireless sensors networks in manufacturing technologies providing the effective integration of information, delivered by sensors of different nature, to achieve a wholesome description of the status of the monitored process. The elaborated algorithm a...

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POWER (power optimization for wireless energy requirements): A MATLAB based algorithm for design of hybrid energy systems

Cited by 11 publications

References 52 publications

Case D: Selection of Power Sources for Portable Applications

Case D: Selection of Power Sources for Portable Applications

Microbattery Technologies for Miniaturized Implantable Medical Devices

Cutting tool vibration energy harvesting for wireless sensors applications

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