System Level Design as Applied to CMU Wearable Computers

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System Level Design as Applied to CMU Wearable Computers

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Journal of VLSI Signal Processing Systems archive
Volume 21 , Issue 3 (July 1999) table of contents
Special issue on system level design

Pages: 251 - 263

Year of Publication: 1999

ISSN:0922-5773

Authors

Asim Smailagic	Institute for Complex Engineered Systems, Carnegie Mellon University, Pittsburgh, PA 15213
Dan Siewiorek	Institute for Complex Engineered Systems, Carnegie Mellon University, Pittsburgh, PA 15213

Publisher

Kluwer Academic Publishers Hingham, MA, USA

Bibliometrics

Downloads (6 Weeks): n/a, Downloads (12 Months): n/a, Citation Count: 4

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abstract references cited by index terms collaborative colleagues

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DOI Bookmark:	10.1023/A:1008131106610

ABSTRACT

The paper describes a system level design approach to the wearable computers project at Carnegie Mellon University (CMU). The project is an unique example of a cross-disciplinary effort, drawing students from mechanical engineering, electrical and computer engineering, computer science, and industrial design. Over the last six and half years that the course has been taught, teams of undergraduate and graduate students have designed and fabricated sixteen new generations of wearable computers, using an evolving artifact-specific, multidisciplinary design methodology. The complexity of their architectures has increased by a factor of over 200, and the complexity of the application has also increased significantly. We introduce a metric to compare wearable computers and show that their performances have increased by several orders of magnitude. A system-level approach to power/performance optimization is going to be a crucial catalyst for making wearable computers an everyday tool for the general public.

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	Daniel P. Siewiorek , Asim Smailagic , Jason C. Y. Lee , Ali-Reza Adl-Tabatabai, Interdisciplinary concurrent design methodology as applied to the navigator wearable computer system, Journal of Computer and Software Engineering, v.2 n.3, p.259-292, 1994
	2	Asim Smailagic , Daniel P. Siewiorek , Drew Anderson , Chris Kasaback , Tom Martin , John Stivoric, Benchmarking an interdisciplinary concurrent design methodology for electronic/mechanical systems, Proceedings of the 32nd ACM/IEEE conference on Design automation, p.514-519, June 12-16, 1995, San Francisco, California, United States [doi>10.1145/217474.217580]
	3	Asim Smailagic , Daniel P. Siewiorek , Richard Martin , John Stivoric, Very rapid prototyping of wearable computers: a case study of custom versus off-the-shelf design methodologies, Proceedings of the 34th annual conference on Design automation, p.315-320, June 09-13, 1997, Anaheim, California, United States [doi>10.1145/266021.266121]
	4	4. C. Amon, A. Smailagic et al. "Concurrent design and analysis of the navigator wearable computer system: The thermal perspective," <i>IEEE Transactions on Components, Hybrids, and Manufacturing Technology</i>, Vol. 18, No. 3, pp. 567-577, Sept. 1995.
	5	Robert Brodersen, InfoPad—an experiment in system level design and integration, Proceedings of the 34th annual conference on Design automation, p.313-314, June 09-13, 1997, Anaheim, California, United States [doi>10.1145/266021.266117]
	6	Walter A. Boring, IV, An integrated testbed for wireless multimedia computing, Journal of VLSI Signal Processing Systems, v.13 n.2-3, p.105-124, Aug./Sept. 1996 [doi>10.1007/BF01130401]
	7	H. de Man , Katholieke Universiteit Leuven/IMEC , Belgium, Invited Address: Future Systems-on-a-Chip: Impact on Engineering Education, Proceedings of the Eleventh International Conference on VLSI Design: VLSI for Signal Processing, p.572, January 04-07, 1998
	8	Asim Smailagic, ISAAC: A Voice Activated Speech Response System for Wearable Computers, Proceedings of the 1st IEEE International Symposium on Wearable Computers, p.183, October 13-14, 1997
	9	Asim Smailagic, An evaluation of audio-centric CMU wearable computers, Mobile Networks and Applications, v.4 n.1, p.59-68, March 1999 [doi>10.1023/A:1019174110066]
	10	10. National Research Council, "Energy-Efficient technologies for the dismounted soldier," <i>National Academy Press, Washington</i>, DC, 1997.
	11	11. D. Siewiorek, "Energy trade-offs in wearable computer design," Institute for Complex Engineering Systems Technical Report, Carnegie Mellon University, 1998.

CITED BY 4

	Luca Benini , Davide Bruni , Alberto Macii , Enrico Macii , Massimo Poncino, Discharge Current Steering for Battery Lifetime Optimization, IEEE Transactions on Computers, v.52 n.8, p.985-995, August 2003
	Chandra Narayanaswami , M. T. Raghunath, Designing a New Form Factor for Wearable Computing, IEEE Pervasive Computing, v.1 n.4, p.42-48, October 2002
	Paul Lukowicz, Guest editorial: Wearable computing and artificial intelligence for healthcare applications, Arificial Intelligence in Medicine, v.42 n.2, p.95-98, February, 2008
	Nagendra Bhargava Bharatula , Paul Lukowicz , Gerhard Tröster, Functionality-power-packaging considerations in context aware wearable systems, Personal and Ubiquitous Computing, v.12 n.2, p.123-141, January 2008