General Related Publications


[1] J. A. Paradiso and T. Starner. Energy scavenging for mobile and wireless electronics. Pervasive Computing, IEEE, 4(1):18-27, 2005.

[2] Thomas von Büren, P. D. Mitcheson, T. C. Green, E. M. Yeatman, A. S. Holmes, and G. Tröster. Optimization of inertial micropower generators for human walking motion. in press, IEEE Sensors Journal, 2005.

[3] Thomas von Büren, Paul Lukowicz, and Gerhard Tröster. Kinetic energy powered computing - an experimental feasibility study. The Seventh International Symposium on Wearable Computers (ISWC 2003), 2003.

[4] Bult K et al 1996 A Distributed, Wireless MEMS Technology for Condition Based Maintenance Proc 1996 Integrated Monitoring, Diagnostics and Failure Prevention Conference, Society of Machine Failure Protection Technology (MPFT) (Mobile, Alabama, USA) pp 373-380

[5] Raghunathan V, Schurgers C, Park S and Skrivastava M B 2002 Energy-Aware Wireless Microsensor Networks IEEE Signal Processing magazine 19 40-50

[6] Enz C C, El-Hoiydi A, Decotignie J-D and Peiris V 2004 WiseNET: An Ultralow-Power Wireless Sensor Network Solution IEEE Computer 37 62 - 70

[7] Warneke B, Last M, Leibowitz B and Pister K S J 2001 Smart Dust: Communicating with a Cubic-Millimeter Computer, IEEE Computer 34 44-51;

[8] Callahan E H Jr 2004 Wireless Sensor Networks (Boca Raton, Florida: CRC Press LLC)

[9] IEEE 802.15.4 Standard, 2003 (New York, The Institute of Electrical and Electronics Engineers, Inc)

[10] Frank R 2004 Move Over, Bluetooth; ZigBee is here Design News 4 (http://www.designnews.com/article/CA387448.html).

[11] Rabaye J, Ammer M J, da Silva J L, Patel D and S Roundy 2000 Picoradio Supports Ad Hoc Ultra-Low Power Wireless Networking IEEE Computer 33 42-48

[12] Puers R 1995 Linking Sensors with Telemetry: Impact on System Design Proc. 8th Int. Conf. on Solid State Sensors and Actuators and Eurosensors IX, (Stockholm, Sweden) pp. 47-50

[13] rfPIC12F675K/675F/675H Data Sheet, Microchip Technology Inc., 2003

[14] Banazwski B and Shah R K 2003 The role of fuel cells for consumer electronic products and toys Proc. 1st Int. Conf. on Fuel Cell Science, Engineering and Technology (Rochester, NY, USA) pp. 149-155

[15] Epstein A H 2004 Millimeter-Scale, Micro-Electro-Mechanical Systems Gas Turbine Engines J. of Engineering Gas Turbines and Power 126 205-226

[16] Tanaka S, Changa K-S, Mina K-B, Satoh D, Yoshida K and Esashi M 2004 MEMS-based components of a miniature fuel cell/fuel reformer system Chemical Engineering Journal 101 143-149

[17] Koeneman P B, Busche-Vishniac I J and Wood K L 1997 Feasibility of micro power supplies for MEMS IEEE J. Microelectomechanical Systems 6 355- 362

[18] Görge G, Kirstein M and Erbel R 2001 Microgenerators for energy autarkic pacemakers and defibrillators: fact or fiction Herz, 26 64-68

[19]. Amirtharajah R and Chandrakasan A. P 1998 Self-Powered Signal Processing Using Vibration-Based Power Generation IEEE J of Solid State Circuits 33 687-695

[20] Jacobson S A and Epstein A H 2003 An informal survey of power MEMS Proc. The Int. Symp. on Micro-Mechanical Engineering ISMME (Japan) pp K18

[21] Kiely J J, Morgan D V and Rowe D M 1991 Low cost miniature thermoelectric generator Electronics Letters 27 2332-2334

[22] Schaevitz S B, Franz A J, Jensen K F and Schmidt M A 2001 A combustion-based MEMS thermoelectric power generator Proc. of the 11th Int. Conf. on Solid-State Sensors and Actuators, Transducers 01( Munich, Germany) pp. 1A3-02

[23] Zhang C, Najafi K, Bernal L P and Washabaugh P D "An Integrated Combustor-Thermoelectric Micro Power Generator Proc. 11th Int. Conf. on Solid-State Sensors and Actuators, Transducers 01( Munich, Germany) pp. 1A3-03

[24] Roundy S, Wright P K and Rabaye J 2003 A study of low level vibrations as a power source for wireless sensor nodes, Computer Communications 26 1131-1144.

[25] Starner T and Paradiso J A 2004 Human Generated Power for Mobile Electronics in Low Power Electronics Design ed C Piguet (Boca Raton, Florida: CRC Press LLC)

[26] von Büren T, Lukowicz P and Tröster G 2003 Kinetic Energy Powered Computing - an Experimental Feasibility Study Proc. 7th IEEE Int. Symposium on Wearable Computers ISWC '03(White Plains, NY) pp. 22-24

[27] Williams C B and Yates R B 1996 Analysis of a micro-electric generator for microsystems Sensors and Actuators A52 8-11

[28] El-Hami M, Glynne-Jones P,James E, Beeby S P, White N M, Brown A D, Ross J N and Hill M 2001 Design and fabrication of a new vibration-based electromechanical power generator Sensors and Actuators A92 335-342

[29] Stephen N G, On energy harvesting from ambient vibration, to be published

[30] Roundy S J 2003 Energy Scavenging for Wireless Sensor Nodes with a Focus on Vibration to Electricity Conversion PhD thesis University of California

[31] Mitcheson P D, Green T C, Yeatman E M, and Holmes A S 2004 Architectures for Vibration-driven Micropower Generators IEEE J. Microelectomechanical Systems 13 429-440

[32] Baudry H 1987 Screen-printing piezoelectric devices Proc. 6th European Microelectronics Conference (London, UK) pp. 456-463

[33] White N M and Turner J D 1997 Thick-film sensors: past, present and future, Meas. Sci.Technol. 8 1-20

[34] Lovinger A J 1983 Ferroelectric Polymers, Science 220 1115-1121.

[35] Nye J F 1957 Physical properties of crystals (Oxford: Oxford University Press)

[36] Richards C D, Anderson M J, Bahr D F and Richards R F 2004 Efficiency of energy conversion for devices containing a piezoelectric component J. Micromech. Microeng. 14 717-721

[37] Goldfarb M and Jones L D 1999 On the efficiency of electric power generation with piezoelectric ceramic Trans. of the ASME Journal of Dynamic Systems, Measurement and Control 121 566-571

[38] IEEE Standard on Piezoelectricity 1987 ANSI/IEEE Standard 176-1987

[39] Piezoelectric Ceramics Data Book for Designers, Morgans Electroceramics

[40] Gonzalez J L, Rubio A and Moll F 2001 A prospect of the of piezoelectric effect to supply power to wearable electronic devices Proc. 4th Int. Conf. on Materials Engineering for Resources (Akita, Japan) pp. 202-207

[41] Umeda M, Nakamura K and Ueha S 1996 Analysis of the Transformation of Mechanical Impact Energy to Electric Energy using Piezoelectric Vibrator Jpn. J. Appl. Phys. 35 3267-3273

[42] Umeda M, Nakamura K and Ueha S 1997 Energy Storage Characteristics of a Piezo-Generator using Impact Induced Vibrations Jpn. J. Appl. Phys. 36 3146-3151

[43] Cavallier B, Nouira H, Foltete E, Hirsinger L and Ballandras S Energy storage capacity of vibrating structure: application to a shock system Proc. Symp. On Design, Test, Integration and Packaging of MEMS/MOEMS DTIP05 (Montreux, Switzerland) pp. 391-393

[44] Xu C-N, Akiyama M, Nonaka K and Watanabe T 1998 Electrical power generation characteristics of PZT piezoelectric ceramics IEEE Trans. UFFC 45 1068-1070

[45] Funasaka T, Furuhata M, Hashimoto Y and Nakamura K 1999 Piezoelectric generator using a LiNbO3 plate with an inverted domain IEEE Ultrasonics Symposium (Honolulu, Hawaii) pp. 959-962

[46] Starner T 1996 Human-powered wearable computing IBM Systems Journal 35 618-629

[47] Antaki J F, B/G??ertocci G E, Green E C, Nadeem A, Rintoul T, Kormos R L and Griffith B P 1995 A gait powered autologous battery charging system for artificial organs American Soc. For Artificial Internal Organs Journal 41 M588-595

[48] Kymissis J, Kendall C, Paradiso J and Gershenfeld N 1998 Parasitic power harvesting in shoes Proc. 2nd IEEE Int. Conf. Wearable Computing (California) pp. 132-139, 1998.

[49] Shenck N. S. and Paradiso J A 2001 Energy scavenging with shoe-mounted piezoelectrics IEEE Micro 21 30-42

[50] Hellbaum R F, Byrant R G and Fox R L 1997 Thin layer composite unimorph ferroelectric driver and sensor US Patent 5,632,841

[51] Yoon H-S Washington G and Danak A 2005 Modelling, Optimisation, and Design of Efficient Initially Curved Piezoceramic Unimorphs for Energy Harvesting Applications J. of Intelligent Material Systems and Structure 16 877-888.

[52] Mateu L and Moll F 2005 Optimum Piezoelectric Bending Beam Structures for Energy Harvesting using Shoe Inserts J. of Intelligent Material Systems and Structure 16 835-845

[53] Drake J 2001 The greatest shoe on earth Wired 9 90-100

[54] Ramsay M J and Clark W W 2001 Piezoelectric energy harvesting for bio MEMS applications Proc. SPIE 4332 429-438

[55] Sohn J W Choi S B and Lee D Y 2005 An investigation on piezoelectric energy harvesting for MEMS power sources Proc. IMechE 219 Part C J. Mechanical Engineering Science 429-436

[56] Platt S R Farritor S Garvin K and Haider H 2005 The Use of Piezoelectric Ceramics for Electric Power Generation Within Orthopedic Implants IEEE/ASME Trans. On Mechatronics 10 455 461

[57] Renaud M Sterken T Fiorini P Puers R Baert K and van Hoof C 2005 Scavenging energy from human body: design of a piezoelectric transducer Tech. Digest 13th Int. Conf. on Solid-State Sensors and Actuators Transducers '05 (Seoul, Korea) Vol. 1 pp. 784-787

[58] White N M, Glynne-Jones P and Beeby S P 2001 A novel thick-film piezoelectric micro-generator Smart Mater. Struct. 10 850-852

[59] Glynne-Jones P, Beeby S P and White N M 2001 Towards a piezoelectric vibration powered microgenerator IEE Proc.-Sci.Meas. Technol. 148 68-72

[60] Glynne-Jones P, Beeby S P and White N M 2001 The modelling of a piezoelectric vibration powered generator for microsystems Proc. 11th Int. Conf. on Solid-State Sensors and Actuators, Transducers 01( Munich, Germany) pp. 46-49

[61] Beeby S P, Blackburn A and White N M 1999 Processing of PZT piezoelectric thick-films on silicon for microelectromechanical systems J. Micromech. Microeng. 218-229

[62] Torah R, Beeby S and White N 2005 An improved thick-film piezoelectric material by powder blending and enhanced processing parameters IEEE Trans UFFC, 52 10-16

[63] Roundy S and Wright P K 2004 A piezoelectric vibration based generator for wireless electronics Smart Materials Structures 13 1131-1142

[64] Sodano H A, Park G and Inman D J 2004 Estimation of Electric Charge Output for Piezoelectric Energy Harvesting Strain 40 49-58

[65] http://www.mide.com/prod_energy_harvester.html

[66] Sodano H A, Magliula E A, Park G and Inman D J 2002 Electric power generation using piezoelectric materials Pro. 13th Int. Conf. on Adaptive Structures and Technologies (Potsdam, Germany) pp. 153-161

[67] Sodano H A, Inman D J and Park G 2004 A Review of power harvesting from vibration using piezoelectric materials Shock and vibration digest 36 197-206

[68] Lu F, Lee H P and S P Lim 2004 Modeling and analysis of micropiezoelectric power generators for micro-electromechanical-systems applications Smart Mater. Struct. 13 57-63

[69] Ng T H and Liao W H 2005 Sensitivity Analysis and Energy Harvesting for a Self-Powered Piezoelectric Sensor J. of Intelligent Material Systems and Structure 16 785-797

[70] Li H, Lal A, Blanchard J and Henderson D 2002 Self-reciprocating radioisotope-powered cantilever J. App. Phys. 92 1122-1127

[71] Lal A and Blanchard J 2004 The daintiest dynamics IEEE Spectrum 41 36-41

[72] Duggirala R, Li H, Pappu A M, Fu Z, Aspel A and Lal A 2004 Radioisotope micropower generator for CMOS self-powered sensor microsystems Proc. 4th Int. Workshop on Micro and Nantechnology for Power Generation and Energy Conversion Applications PowerMEMS 2004 (Kyoto, Japan) pp. 133-136

[73] Marzencki M, Basrour S, Charlot B, Grasso A, Colin M and Valbin L 2005 Design and fabrication of piezoelectric micro power generators for autonomous microsystems Proc. Symp. On Design, Test, Integration and Packaging of MEMS/MOEMS DTIP05 (Montreux, Switzerland) pp. 299-302

[74] Jeon Y B Sood R Jeong J-h and Kim S G 2005 MEMS power generator with transverse mode thin film PZT Sensors and Actuators A 122 16-22

[75] Sodano H A, Park G, Leo D J and Inman D J 2003 Use of piezoelectric energy harvesting devices for charging batteries Proc. SPIE 10th Annual Int. Symp. On Smart Structures and Materials (San Diego, CA, USA) pp. 101-108

[76] Sodano H A, Park G and Inman D J 2003 An investigation into the performance of macro-fiber composites for sensing and structural vibration application Mechanical Systems and Signal Processing 18 683-697

[77] Wilkie W K, Bryant R G, High J W, Fox R L, Hellbaum R F, Jalink A, Little B D and Mirick P H 2000 Low cost piezocomposite actuator for structural control applications Proc. 7th SPIE Int. Symp. On Smart Structures and Materials (Newport Beach, CA) pp. 323-334

[78] Sodano H A, Lloyd J and Inman D J 2004 An experimental comparison between several active composite actuators for power generation Proc. SPIE 5390 370-378

[79] Sodano H A, Inman D J and Park G 2005 Comparison of Piezoelectric Energy Harvesting Devices for Recharging Batteries J. of Intelligent Material Systems and Structures 16 799-807

[80] Elvin N G, Elvin A A and Spector M 2001 A self-powered mechanical strain energy sensor Smart Matter. Struct. 10 293-299

[81] Dogheche K, Cavallier B, Delobelle P, Hirsinger L, Cattan E, Remiens D, Marzencki M, Charlot B, Basrour S, and Ballandras S 2005 A bi-stable micro-machined piezoelectric transducer for mechanical to electrical energy transformation, Proc. Symp. On Design, Test, Integration and Packaging of MEMS/MOEMS DTIP05 (Montreux, Switzerland) pp. 303-304

[82] Kim S, Clark W W, and Wang Q-M 2005 Piezoelectric Energy Harvesting with a Clamped Circular Plate: Analysis J. of Intelligent Material Systems and Structure 16 847-854

[83] Kim S, Clark W W, and Wang Q-M 2005 Piezoelectric Energy Harvesting with a Clamped Circular Plate: Experimental Study J. of Intelligent Material Systems and Structure 16 855-863

[84] Allen J J and Smits A J 2001 Energy Harvesting Eel J. of Fluids and Structures 15 629-640

[85] Williams CB, Shearwood C, Harradine M A, Mellor P H, Birch T S and Yates R B 2001 Development of an electromagnetic micro-generator IEE Proc.-Circuits Devices Syst. 148 (6) 337-342

[86] Williams C W and Yates R B 1996Analysis of a micro-electric generator for Microsystems Sensors and Actuators A52 8-11

[87] Williams C W, Woods R C and Yates R B Feasibility of a vibration powered micro-electric generator, IEE Colloquium, 1996, 7/1-7/3

[88] Shearwood C and Yates R B 1997 Development of an electromagnetic micro-generator, Electronics Letters 33 (22) 1883-1884]

[89] Glynne-Jones P, Tudor M J, Beeby S P, White N M 2004 An electromagnetic, vibration-powered generator for intelligent sensor systems, Sensors and Actuators, A110 344-349

[90] Amirtharajah R, Chandrakasan A P, Self-powered signal processing using vibration-based power generation, IEEE Journal of Solid-State Circuits 33, 1998, 687-695

[91] Li W J, Wen Z, Wong P K, Chan G M H, Leong P H W 2000 A micromachined vibration-induced power generator for low power sensors of robotic systems, World Automation Congress: 8th International Symposium on Robotics with Applications, Hawaii

[92] Ching N N H, Wong H Y, Li W J, Leong P H W, Wen Z A laser-micromachined vibrational to electrical power transducer for wireless sensing systems, Sensors and Actuators, A 97-98, 2002, 685-690

[93] Mizuno M and Chetwynd D 2003 Investigation of a resonance microgenerator, J.Micromech. Microeng. 13 209-216

[94] Kulah H, Najafi K 2004 An electromagnetic micro power generator for low-frequency environmental vibrations, Micro Electro Mechanical Systems: 17th IEEE Conference on MEMS, Maastricht, 237-240

[95] Huang W S, Tzeng K E, Cheng, M C and Huang R S 2003 Design and fabrication of a vibrational micro-generator for wearable MEMS Proceedings of Eurosensors XVII, Guimaraes, Portugal 695-697

[96] Pérez-Rodríguez A, Serre C, Fondevilla N, Cereceda C, Morante J R, Esteve J, Montserrat J 2005 Design of electromagnetic inertial generators for energy scavenging applications Proceeedings of Eurosensors XIX, Barcelona, Spain, paper MC5

[97] Beeby S P, Tudor M J, Koukharenko E, White N M, O'Donnell T, Saha C, Kulkarni S and Roy S 2005 Micromachined silicon generator for harvesting power from vibrations Proceedings of Transducers 2005, Seoul, Korea, pages

[98] www.kinetron.nl

[99] www.perpetuum.co.uk

[100] www.ferrosi.com

[101] S Roundy, P Wright and K Pister 2002 Micro-electrostatic vibration-to-electricity converters Proceeding of IMECE 2002 pp. 1-10.

[102] S Meninger 1999 A low power controller for a MEMS based energy converter MSc Massachusetts Institute of Technology

[103] G Despesse, T Jager, J Chaillout, J Leger, A Vassilev, S Basrour and B Chalot 2005 Fabrication and characterisation of high damping electrostatic micro devices for vibration energy scavenging Proc. Design, Test, Integration and Packaging of MEMS and MOEMS pp. 386-390.

[104] S Roundy 2003 Energy scavenging for wireless sensor nodes with a focus on vibration to electricity conversion PhD Thesis University of Berkeley

[105] S Meninger, J Mur-Miranda, J Lang, A Chandrakasan, A Slocum, M Schmidt and R Amirtharajah 2001 Vibration to electric energy conversion IEEE Trans Very Large Scale Integration (VLSI) Systems Vol 9(1) pp. 64-76.

[106] W Ma, M Wong and L Ruber 2005 Dynamic simulation of an implemented electrostatic power micro-generator Proc. Design, Test, Integration and Packaging of MEMS and MOEMS pp. 380-385.

[107] R Tashiro, N Kabei, K Katayama, F Tsuboi, K Tsuchiya 2002 Development of a electrostatic generator for a cardiac pacemaker that harnesses the ventricular wall motion J Artif Organs pp. 239-245.

[108] R Tashiro, N Kabai, K Katayama, Y Ishizuka, F Tsuboi and K Tsuchiya 2000 Development of an electrostatic generator that harnesses the motion of a living body JSME International Journal Series C Col 43 No 4 pp.916-922.

[109] M Miyazaki, H Tanaka, G Ono, T Nagano, N Ohkubo, T Kawahara and K Yano 2003 Electric-energy generation using variable-capacitive resonator for power-free LSI: efficiency analysis and fundamental experiment ISLPED '03 pp.193-198.

[110] P Miao, P Micheson, A Holmes, E Yeatmam, T Green and B Stark 2005 MEMs inertial power generators for biomedical applications Proc. Design, Test, Integration and Packaging of MEMS and MOEMS pp. 295-298

[111] P Mitcheson, B Stark, P Miao, E Yeatman, A Holmes and T Green Analysis and optimisation of MEMS on-chip power supply for self powering of slow moving sensors, In Eurosensors'03, Portugal, pages 48-51, September 2003.

[112] T Sterken, K Baert, R Puers and S Borghs Power extraction from ambient vibration Proc 3rd workshop on semiconductor sensors and actuators pp. 680-683
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[113] T Sterken, P Fiorini, K Baert, G Borghs and R Puers 2004 Novel design and fabrication of a MEMS electrostatic vibration scavenger PowerMEMS Conference Kyoto Japan pp. 18-21.

[114] Y Arakawa, Y Suzuki and N Kasagi 2004 Micro seismic power generator using electret polymer film PowerMEMS Conference Kyoto Japan pp. 187-190.

[115] F Peano and T Tambosso 2005 Design and optimisation of a MEMS electret-based capacitive energy scavenger J of Microelectromechanical Systems Vol 14 No 3 pp.529-435.

[116 ] M Mizuni and D Chetwynd 2003 Investigation of a resonance microgenerator J. Micromech. Microeng. 13 pp.209-216.

[117] Huang J, O'Handley R C and Bono D 2003 New, high-sensitivity, hybrid magnetostrictive/electroactive magnetic field sensors Proc. SPIE 5050 229-237

[118] Bayrashev A, Robbins W P and Ziaie B 2004 Low frequency wireless powering of microsystrems using piezoelectric-magnetostrictive laminate composites Sensors and Actuators A114 244-249

[119] Roundy S 2005 On the Effectiveness of Vibration-based Energy Harvesting J. of Intelligent Material Systems and Structure 16 809-823

[120] Hills P 1999 Condition management review Insight 41(12) 784-791

[121] Kansal A and Srivastava M B 2003 An Environmental Energy Harvesting Framework for Sensor Nodes Proc of the 2003 Int. Symp on Low Power Electronics and Design ISLPED'03 (Seoul, Korea) pp. 481-486