NSF Org:	CNS Division Of Computer and Network Systems
Recipient:	UNIVERSITY OF CALIFORNIA, LOS ANGELES
Initial Amendment Date:	July 8, 2005
Latest Amendment Date:	June 2, 2007
Award Number:	0453809
Award Instrument:	Continuing Grant
Program Manager:	Victor S. Frost CNS  Division Of Computer and Network Systems CSE  Directorate for Computer and Information Science and Engineering
Start Date:	July 15, 2005
End Date:	June 30, 2009 (Estimated)
Total Intended Award Amount:	$0.00
Total Awarded Amount to Date:	$856,987.00
Funds Obligated to Date:	FY 2005 = $286,304.00 FY 2006 = $297,034.00 FY 2007 = $273,649.00
History of Investigator:	Deborah Estrin (Principal Investigator) destrin@cs.cornell.edu William Kaiser (Co-Principal Investigator) Mani Srivastava (Co-Principal Investigator) Edward Kohler (Co-Principal Investigator) Richard Guy (Co-Principal Investigator)
Recipient Sponsored Research Office:	University of California-Los Angeles 10889 WILSHIRE BLVD STE 700 LOS ANGELES CA  US  90024-4200 (310)794-0102
Sponsor Congressional District:	36
Primary Place of Performance:	University of California-Los Angeles 10889 WILSHIRE BLVD STE 700 LOS ANGELES CA  US  90024-4200
Primary Place of Performance Congressional District:	36
Unique Entity Identifier (UEI):	RN64EPNH8JC6
Parent UEI:
NSF Program(s):	CCRI-CISE Cmnty Rsrch Infrstrc
Primary Program Source:	app-0105  app-0106  app-0107
Program Reference Code(s):	9218, 9232, HPCC
Program Element Code(s):	735900
Award Agency Code:	4900
Fund Agency Code:	4900
Assistance Listing Number(s):	47.070

ABSTRACT

Wireless embedded systems are invigorating CISE research areas from operating systems, distributed embedded computing, architecture, and networking to signal processing, algorithms, and data management, and opening up new broad-impact applications ranging from wide area environmental management to biomedical monitoring. These systems are increasingly focused on a particularly powerful and exciting class of deployment: the heterogeneous or tiered sensor network. A heterogeneous sensor network contains nodes with different capabilities, such as tiny, low-power "motes" and higher-powered, "microservers". Motes are inexpensive and require no infrastructure for long-term deployments, but also extremely constrained in memory, CPU power, and communication. Microservers, in contrast, are more efficient than motes at many computation- and memory-intensive tasks, and more readily interfaced to high-bandwidth peripherals, such as high-rate ADCs and network interfaces; but their higher energy consumption requires power infrastructure, such as solar panels, in long-term deployments. A heterogeneous system containing both motes and microservers can combine the advantages of both devices, using motes to achieve the desired spatial sensing density and microservers to achieve the desired processing power.

Wireless embedded sensor systems present the CISE community with an array of intertwined research challenges: real time sensing of complex and diverse phenomena, embedded computing constrained in bandwidth, energy, memory, and storage, controlled mobility, and the autonomous coordination of vast numbers of network nodes. But implementing and testing sensor network applications is daunting even aside from these challenges: many of the constraints that yield low-power, long-lifetime systems also undermine traditional methods for instrumenting and understanding program behavior. Coordinated community infrastructure can thus act as a tremendous research accelerator, and without shared infrastructure, research in the field will be significantly hampered. This project addresses a pressing need: wireless sensor network research demands a concentrated effort to develop a community resource for heterogeneous sensor systems.

The investigators will develop a community resource based on Emstar, a highly resilient application methodology for microservers and general heterogeneous deployments. Emstar smoothly combines simulation, emulation, and deployment, leading to qualitatively easier debugging and application analysis. An EmTOS component seamlessly integrates motes and microservers; the EmView visualizer provides unprecedented visibility into wireless sensor network communication patterns.

This will build on the investigators Emstar prototype which has proven its value in deployments of heterogeneous networks.
With expanded functionality, integration, hardening, enhanced usability, and longer-term support, its broad array of tools will become accessible to the computer and information science and engineering community. The project will expand Emstar's flexibility, completeness, robustness, documentation, and programmability; extend its functionality by learning from targeted deployments such as seismic arrays, mobile environmental sensing, and medical informatics; and develop a robust, active Emstar community through workshops, tutorials, and mailing lists. The proposed community resource will act as a tremendous accelerator for research into heterogeneous wireless sensor networks, enabling quick and thorough exploration of socially important applications including environmental monitoring, medical and public health systems, and industrial and civic infrastructure development and management. The project will also support and develop undergraduate and graduate level project courses using Emstar, and explicitly involve an undergraduate research program targeting underrepresented minorities.

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