NASA SBIR 2008 Solicitation

FORM B - PROPOSAL SUMMARY


PROPOSAL NUMBER: 08-2 O2.02-9981
PHASE 1 CONTRACT NUMBER: NNX09CF51P
SUBTOPIC TITLE: Ground Test Facility Instrumentation
PROPOSAL TITLE: Passively Powered and Programmable Sensor-RFID for ISHM Systems

SMALL BUSINESS CONCERN (Firm Name, Mail Address, City/State/Zip, Phone)
Mobitrum Corporation
8070 Georgia Avenue, Suite 207
Silver Spring, MD 20910 - 4948
(301) 585-4040

PRINCIPAL INVESTIGATOR/PROJECT MANAGER (Name, E-mail, Mail Address, City/State/Zip, Phone)
Ray Wang
ray_wang@mobitrum.com
8070 Georgia Avenue, Suite 207
Silver Spring, MD 20910 - 4948
(301) 585-4040

Expected Technology Readiness Level (TRL) upon completion of contract: 4 to 5

TECHNICAL ABSTRACT (Limit 2000 characters, approximately 200 words)
To date there are several approaches for incorporating sensing capabilities into RFID. Active tags use batteries to power their communication circuitry, sensors, and microcontroller. Active tags benefit from relatively long wireless range and can achieve high data and sensor activity rates. However, the batteries required by active tags are disadvantageous for device cost, lifetime, weight, and volume. In contrast, passive sensor tags receive all of their operating power from external RF transmitting sources and are not limited by battery life. One attractive feature of passive sensor tags is the prospect of permanently embedding them in objects for structural monitoring. Another is their suitability for applications in which neither batteries nor wired connections are feasible, for weight, volume, cost, or other reasons. A limitation of purely passive sensor tags is the requirement of proximity to a RF transmitter. Since lower power consumption is one major trend in RF circuit design, a self-powered system by means of energy harvesting becomes very attractive. It can serve as the enabling technology for novel applications such as ambient intelligence. Using a power harvesting technique for wireless rechargeable battery smart sensor and enhanced RFID are the key elements for successfully distributing sensors across sensor networks.

POTENTIAL NASA COMMERCIAL APPLICATIONS (Limit 1500 characters, approximately 150 words)
Ground testing of propulsion systems is a critical requirement to enable NASA's New Vision for space exploration. The proposed power harvesting technology for sensor and RFID applications will enable a cost effective remote testing and health monitoring through shared sensor networks. Mobitrum anticipates the following applications that NASA will benefit from the proposed technology: 1) Data analysis, processing, and visualization for Earth science observations, 2) Rocket engine test, 3) Remote test facility management, 3) Field communications device for spatial data input, manipulation and distribution, 4) Sensor, measurement, and field verification applications, 5) RFID for identification and tracking, 6) Condition-aware applications, 7) Location-aware applications, 8) Biometric identification applications, 9) Data collaboration and distribution applications, 10) Wireless instrumentation for robotic manipulation and positioning for audio and visual capture, and real-time multimedia representation.

POTENTIAL NON-NASA COMMERCIAL APPLICATIONS (Limit 1500 characters, approximately 150 words)
The proposed passively powered and programmable sensor-RFID device may apply to many commercial applications: 1) Medical RFID, 2) In-vehicle network the device could be used to network drive train electronic control units and communication systems for body electronics, 3) Aircraft and aerospace electronics the device could be a backbone network in aircrafts for flight state sensors, navigation systems and research PCs driving displays installed in the cockpit, 4) Home control the device could be sensor centric for Internet-based home utility control. This application would create a new service from the Internet Service provider, 5) Energy management for cost saving the device is an idea platform to integrate various sensors for energy management to save cost, 6) Security (intruder detection), 7) Safety (sensing), 8) Utility remote meter reading, 9) Building automation systems real-time monitoring and control of security and surveillance systems, alarms, HVAC, 10) Manufacturing and distribution industrial automation using RFID.

NASA's technology taxonomy has been developed by the SBIR-STTR program to disseminate awareness of proposed and awarded R/R&D in the agency. It is a listing of over 100 technologies, sorted into broad categories, of interest to NASA.

TECHNOLOGY TAXONOMY MAPPING
Airport Infrastructure and Safety
Architectures and Networks
Attitude Determination and Control
Autonomous Control and Monitoring
Autonomous Reasoning/Artificial Intelligence
Ceramics
Computational Materials
Computer System Architectures
Data Acquisition and End-to-End-Management
Data Input/Output Devices
Database Development and Interfacing
Earth-Supplied Resource Utilization
Energy Storage
Expert Systems
General Public Outreach
Highly-Reconfigurable
Human-Computer Interfaces
Human-Robotic Interfaces
Instrumentation
Integrated Robotic Concepts and Systems
Intelligence
K-12 Outreach
Manned-Maneuvering Units
Mission Training
Mobility
Operations Concepts and Requirements
Perception/Sensing
Portable Data Acquisition or Analysis Tools
Portable Life Support
Production
RF
Radiation Shielding Materials
Semi-Conductors/Solid State Device Materials
Sensor Webs/Distributed Sensors
Simulation Modeling Environment
Software Development Environments
Software Tools for Distributed Analysis and Simulation
Solar
Spaceport Infrastructure and Safety
Substrate Transfer Technology
Telemetry, Tracking and Control
Testing Facilities
Testing Requirements and Architectures
Tools
Training Concepts and Architectures
Ultra-High Density/Low Power
Wireless Distribution


Form Generated on 08-03-09 13:26