**5. References**


[9] Jean-Mistral, C., S. Basrour, and J.J. Chaillout (2008) *Dielectric polymer: scavenging energy from human motion.* Proc. SPIE. 6927: p. 692716.

182 Smart Actuation and Sensing Systems – Recent Advances and Future Challenges

monitors, and video gaming interfaces.

Thomas G. McKay and Benjamin M. O'Brien

**Author details** 

Iain A. Anderson

*Auckland, New Zealand* 

**Acknowledgement** 

*Level 6, Auckland, New Zealand* 

*Level 6, Auckland, New Zealand* 

O'Brien, and Suzie Pilkington.

*USENIX ATC '10.*

26, Supplement 1(0): p. 41-51.

319(5864): p. 807-810.

764209-12.

**5. References** 

Ltd.

network of sensors and smart devices that will improve future prosthetic devices, sports

*The Biomimetics Laboratory of the Auckland Bioengineering Institute, The University of Auckland,* 

*The Biomimetics Laboratory of the Auckland Bioengineering Institute, The University of Auckland,* 

*Department of Engineering Science, School of Engineering, The University of Auckland, Level 3,* 

This work was supported by a University of Auckland Bioengineering Institute FRDF postdoctoral fellowship and a Rutherford Foundation postdoctoral fellowship from the Royal Society of New Zealand. The authors acknowledge the support of the Auckland Bioengineering Institute, their colleagues in the Biomimetics lab, Kristal Murray, Michelle

[2] Schiffer, M.B. and C.L. Bell (2003) *Draw the Lightening Down: Benjamin Franklin and Electrical Technology in the Age of Enlightenment.* Berkeley: University of California Press,

[3] Jia, D. and J. Liu (2009) *Human power-based energy harvesting strategies for mobile electronic* 

[4] Carroll, A. and G. Heiser (2010) *An Analysis of Power Consumption in a Smartphone.* 

[5] Starner, T. and J.A. Paradiso (2004) *Human Generated Power for Mobile Electronics* in *Low* 

[6] Shorten, M.R. (1993) *The energetics of running and running shoes.* Journal of Biomechanics.

[7] Donelan, J.M., Q. Li, V. Naing, J.A. Hoffer, D.J. Weber, and A.D. Kuo (2008) *Biomechanical Energy Harvesting: Generating Electricity During Walking with Minimal User Effort.* Science.

[8] Jean-Mistral, C. and S. Basrour (2010) *Scavenging energy from human motion with tubular dielectric polymerElectroactive Polymer Actuators and Devices (EAPAD) 2010* 7642: p.

*devices.* Frontiers of Energy and Power Engineering in China. 3(1): p. 27-46.

*Power Electronics Design* C. Piguet Editor CRC Press. p. 45-1 - 45-35.

[1] *Adidas miCoach*. 2012 [cited 2012]; Available from: www.micoach.com/.

	- [28] Kaltseis, R., C. Keplinger, R. Baumgartner, M. Kaltenbrunner, T. Li, P. Machler, R. Schwdiauer, Z. Suo, and S. Bauer (2011) *Method for measuring energy generation and efficiency of dielectric elastomer generators.* Appl. Phys. Lett. 99(16): p. 162904.
	- [29] Koh, S.J.A., X. Zhao, and Z. Suo (2009) *Maximal energy that can be converted by a dielectric elastomer generator.* Appl. Phys. Lett. 94(26): p. 262902.
	- [30] O'Brien, B.M. and I. Anderson (2011) *An Artificial Muscle Ring Oscillator.* Mechatronics, IEEE/ASME Transactions on. PP(99): p. 1-4.
	- [31] O'Brien, B.M., E.P. Calius, T. Inamura, S.Q. Xie, and I.A. Anderson (2010) *Dielectric Elastomer Switches for Smart Artificial Muscles.* Applied Physics A: Materials Science & Processing. 100: p. 385-389.
	- [32] O'Brien, B.M., T.G. McKay, S.Q. Xie, E.P. Calius, and I.A. Anderson (2011) *Dielectric Elastomer memory*. Proc. SPIE. 7976: p 797621-7.
