BISMAC control using SMA resistance feedback

Proceedings of SPIE - The International Society for Optical Engineering

Volumn 7642, Issue , 2010, Pages

  Villanueva, Alex ^a   Priya, Shashank ^a,b  

^a State University   (United States)

^b VIRGINIA POLYTECHNIC INSTITUTE AND STATE UNIVERSITY   (United States)

Author keywords

Actuator; Bio inspired; BISMAC; Feedback control; Jellyfish; Shape memory alloy

Indexed keywords

AURELIA; BIAS SPRINGS; BIO-INSPIRED; BIO-METAL FIBERS; CURRENT INPUT; DRIVING CURRENT; ENERGY CONSUMPTION; LOW CURRENTS; MEDUSAE; OVERHEATING EFFECTS; PEAK CURRENTS; POWER CONSUMPTION; RESISTANCE FEEDBACK; SHAPE MEMORY ALLOY; SHAPE MEMORY ALLOY COMPOSITES; SMA WIRE; THRESHOLD RESISTANCE;

ACTUATORS; ALLOYS; CONDUCTING POLYMERS; DEFORMATION; FEEDBACK CONTROL; SHAPE MEMORY EFFECT; WIRE;

CONTROLLERS;

EID: 77953281572     PISSN: 0277786X     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1117/12.847788     Document Type: Conference Paper

References (14)

1. Villanueva A, Bresser S, Chung S, Tadesse Y, and Priya S 2009 Jellyfish inspired underwater unmanned vehicle Proc. SPIE 7287, 72871G, DOI:10.1117/12.815754
2. Bunget, G., S. Seelecke, et al. (2009). "Design and Fabrication of a Bio-Inspired Flapping Flight Micro-Air Vehicle." Smasis 2008: Proceedings of the Asme Conference on Smart Materials, Adaptive Structures and Intelligent Systems - 2008, Vol 2: 647-654720.
3. Guo S, Fukuda T, Asaka K 2003 A new type of fish-like underwater microrobot IEEE/ASME Trans Mechatronics, pp.136-141
4. Yang Y, Ye X, Guo S 2007 A New Type of Jellyfish-Like Microrobot Proceeding of the 2007 IEEE Intl. Conference on Integration Technology
5. Wang Z, Hang G, Wang Y, Li J, Du Wei 2008 Embedded SMA wire actuated biomimetic fin: a module for biomimetic underwater propulsion, IOP, SMS 17,025039, Harbin, China
6. Villanueva A, Joshi K , Blottman J, Priya S 2010 A bio-inspired shape memory alloy composite (BISMAC) actuator, IOP, SMS, 19, 025013
7. Kuribayashi, K. (1991). "Improvement of the Response of an SMA Actuator Using a Temperature Sensor." International Journal of Robotics Research 10(1): 13-20.
8. Webb G, Wilson L, Lagoudas DC & Rediniotis O (2000). Adaptive control of shape memory alloy actuators for underwater biomimetic applications. AIAA Journal, 38: 325-334. (Pubitemid 30564649)
9. R. Featherstone & Y. H. Teh 2004. Improving the Speed of Shape Memory Alloy Actuators by Faster Electrical Heating. Int. Symp. Experimental Robotics (ISER'04), Singapore, 18-21 June 2004.
10. Teh, Y. H. and R. Featherstone (2008). "An architecture for fast and accurate control of shape memory alloy actuators." International Journal of Robotics Research 27(5): 595-611
11. Mukherjee, R., T. F. Christian, et al. (1996). "An actuation system for the control of multiple shape memory alloy actuators." Sensors and Actuators a-Physical 55(2-3): 185-192.
12. Raparelli, T., P. B. Zobel, et al. (2002). "A robot actuated by shape memory alloy wires." Isie 2002: Proceedings of the 2002 Ieee International Symposium on Industrial Electronics, Vols 1-4: 420-4231409.
13. Song, G. B., N. Ma, et al. (2007). "Position estimation and control of SMA actuators based on electrical resistance measurement." Smart Structures and Systems 3(2): 189-200.
14. Takeda, Y., H. Cho, et al. (2009). "Control Characteristics of Shape Memory Alloy Actuator Using Resistance Feedback Control Method." State-of-the-Art Research and Application of Smas Technologies 59: 178-183210.