Robust and low complexity rate control for solar powered sensors

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Robust and low complexity rate control for solar powered sensors

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Design, Automation, and Test in Europe archive
Proceedings of the conference on Design, automation and test in Europe table of contents

Munich, Germany

SESSION: Advanced power management techniques table of contents

Pages 230-235

Year of Publication: 2008

ISBN:978-3-9810801-3-1

Authors

Clemens Moser	Swiss Federal Institute of Technology Zurich
Lothar Thiele	Swiss Federal Institute of Technology Zurich
Davide Brunelli	University of Bologna
Luca Benini	University of Bologna

Sponsors

: IEEE Council on Electronic Design Automation (CEDA)
EDAA : European Design Automation Association
: The EDA Consortium
SIGDA: ACM Special Interest Group on Design Automation
RAS : RAS
: The IEEE Computer Society TTTC
: ECSI

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ACM New York, NY, USA

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Downloads (6 Weeks): 8, Downloads (12 Months): 52, Citation Count: 1

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ABSTRACT

This paper is concerned with solar driven sensors deployed in an outdoor environment. We present feedback controllers which adapt parameters of the application such that a maximal utility is obtained while respecting the time-varying amount of available energy. We show that already simple applications lead to complex optimization problems, involving unacceptable running times and energy consumptions for resource constrained nodes. In addition, naive designs are highly susceptible to energy prediction errors. We address both issues by proposing a hierarchical control approach which both reduces complexity and increases robustness towards prediction uncertainty. As a key component of this hierarchical approach, we propose a new worst-case energy prediction algorithm which guarantees sustainable operation. All methods are evaluated using long-term measurements of solar energy in an outdoor setting. Furthermore, we measured the implementation overhead on a real sensor node.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	Jan Beutel , Matthias Dyer , Martin Hinz , Lennart Meier , Matthias Ringwald, Next-generation prototyping of sensor networks, Proceedings of the 2nd international conference on Embedded networked sensor systems, November 03-05, 2004, Baltimore, MD, USA [doi>10.1145/1031495.1031541]
	2	F. Borrelli, M. Baotic, A. Bemporad, and M. Morari. Efficient On-Line Computation of Constrained Optimal Control. In IEEE Conference on Decision and Control, pages 1187--1192, Orlando, Florida, Dec. 2001.
	3	F. Borrelli, A. Bemporad, and M. Morari. A Geometric Algorithm for Multi-Parametric Linear Programming. Journal of Optimization Theory and Appl., 118(3):515--540, Sept. 2003.
	4	Xiaofan Jiang , Joseph Polastre , David Culler, Perpetual environmentally powered sensor networks, Proceedings of the 4th international symposium on Information processing in sensor networks, April 24-27, 2005, Los Angeles, California
	5	Aman Kansal , Jason Hsu , Sadaf Zahedi , Mani B. Srivastava, Power management in energy harvesting sensor networks, ACM Transactions on Embedded Computing Systems (TECS), v.6 n.4, p.32-es, September 2007 [doi>10.1145/1274858.1274870]
	6	M. Kvasnica, P. Grieder, and M. Baotić. Multi-Parametric Toolbox (MPT), 2004.
	7	Bern University of Applied Sciences, Engineering and Information Technologies, Photovoltaic Laboratory. Recordings of solar light intensity at Mont Soleil from 01/01/2002 to 31/09/2006. www.pvtest.ch, March, 2007.
	8	Moteiv Corporation. Tmote sky - ultra low power ieee 802.15.4 compliant wireless sensor module, datasheet. http://www.moteiv.com/products/docs/tmote-sky-datasheet.pdf.
	9	Clemens Moser , Lothar Thiele , Davide Brunelli , Luca Benini, Adaptive power management in energy harvesting systems, Proceedings of the conference on Design, automation and test in Europe, April 16-20, 2007, Nice, France
	10	Farhan Simjee , Pai H. Chou, Everlast: long-life, supercapacitor-operated wireless sensor node, Proceedings of the 2006 international symposium on Low power electronics and design, October 04-06, 2006, Tegernsee, Bavaria, Germany [doi>10.1145/1165573.1165619]