Submission of proposals

1) Bowman, L. "A Stirling Micro-Refrigerator for Cold Electronics", NSF Final Project Report, NSF SGER Award No. CTS-9115773, 1991

2) Bowman, L. "Oscillating Flow in Sirling Micro-Refrigerators: Empirical Verification of Analytical Results", NSF Final Project Report, NSF Phase I SBIR Award No. ISI-9160269, 1992.

3) Bowman, L., McEntee, J., "Diaphram Actuator for a Stirling Microrefrigerator", NASA SBIR 91-1, Phase I Final Report, NASA Contract no. NAS5-31940, 1992.

4) Jiang L., Koo J. M., Zeng S., Zhang L., Banerjee S., Zhou P., Santiago J. G., Kenny T. W., Goodson K. E., 2001, "An Electrokinetic Closed-Loop Micro Cooler for High-Power VLSI Chips," to be presented at SEMI-THERM, San Jose, CA, USA, March.

5) McEntee, J., Bowman, L., "Oscillating Diaphrams", Technical Proceedings of the 1999 International Conference on Modeling and Simulation of Microsystems, pp597-600.

6) Shinde, N., Bashir, R., Groll, E., Chieu, G., "Design, Fabrication, and Heat Flow Analysis of a Mesoscopic Pulse Tube for Integrated Micro-Refrigeration Systems", 2000 International Mechanical Engineering Congress and Exposition, American Society of Mechanical Engineers, November 5th -10th, 2000, Orlando, Florida.
KEYWORDS: Micro-fluidics, MEMS, cryo-coolers

A02-099 TITLE: Developing Spectrum Sharing Technique and Demonstrating its Application
TECHNOLOGY AREAS: Information Systems
ACQUISITION PROGRAM: PM, Tactical Radio Communications Systems
OBJECTIVE: To enhance the spectrum utilization efficiency in the future combat system (FCS), a new approach called spectrum sharing needs to be investigated. The basic technique for spectrum sharing, its advantage and its limitation need to be studied. As applied to Homeland Defense, greater spectrum utilization efficiency and more reliable data and voice wireless communication will result.
DESCRIPTION: There is a critical need to develop new techniques to increase the spectrum utilization in the combat communication system. Spectrum scarcity is a well-known problem. With the increase in the demand of high-speed communication, the spectrum scarcity has increased manifold. In order to overcome this problem, US Department of Defense (DoD) is investigating this issue by developing new techniques to increase the spectrum utilization efficiency. One of the approaches is the spectrum sharing. In this approach, communication is performed with dynamic frequency allocation where techniques are used to determine the unused spectrum in time and space, and than communication is established at certain time with certain spectrum, which is constantly monitored. In this way, during communication the spectrum is constantly shared with other users. There are several techniques to activate this optimization, such as methods for the secondary receivers to measure the background where it eliminates the self-generated interference and identifies the secondary signal to all primary users and finally modifies the frequency assignments to mitigate interference.
As a first step to address the problem, basic technique for such spectrum sharing needs to be established. This will include requirements such as:
- High sensitivity to avoid false positive spectrum usage detections.

- Very high dynamic range to avoid harmonic and inter-modulation signals appearing to be valid primary users.

- Special algorithms to help reject false detections, otherwise, excessive interference or insufficient amount of harvested spectrum. However, scanning fast is not a critical requirement, many bands with low usage and harvest these bands first.

- Need special active probing methods in broadcast bands and in bands with low duty cycle as listening alone will not prevent interference to primary users.

1) DARPA Web site and other DARPA Programs covering Optical Technologies, trade journals in optical networking technologies, CECOM/DARPA Future Combat Systems (FCS) Program.

1) Chu, Ruey-Shi, "Analysis of Continuous Transverse Stub (CTS) Array by Floquet Mode Method, " 1998 IEEE International Antennas and Propagation Symposium and USNC/URSI National Radio Science Meeting, Atlanta, GA, USA. Part 2 (of 4), Jun 21-26, 1998, v2, 1998.

The low cost and low power will enable large numbers of networked sensors to be deployed and to provide an enhanced level of security at airports and

other transportation terminals. The affordability of the devices and components will allow them to be deployed in large numbers with little maintenance and other support for long periods of time. As these VLSI protocols are independent of the attached sensor technology, they may be used in a wide variety of sensor systems.
PHASE I: In this phase, the available options for channel access and routing will be assessed and implementation and power tradeoffs be performed. Then an overall protocol architecture will be defined, clearly indicating the tradeoffs that were made in the development of the architecture. The protocol architecture definition should include power consumption, network system performance as well as address VLSI implementation. Typically, these applications may range in the 1000's or 10,000's nodes, and hence low cost is a critical issue. Low power is an obvious requirement to avoid battery changes (where and if possible) and to provide an extended sensor/munitions field operational lifetime. In addition, it may be possible to link diifferent types of sensors (acoustic, motion, visual, IR, etc.) directly to a munitions device or group of devices to provide greater converage and kill probability. Finally, the sensors/munitions platforms may be directly or indirectly linked to an associated C2 system to provide real time monitoring, status and surveillance capabilities. The resultant performance shall be estimated, as well as techniques for providing flexible and adaptive protocol operation to be designed and developed. The results of this first phase must be a protocol design specified in a formal language such as SDL or VHDL.
PHASE II: In this phase, prototype implementations shall be made for the protocols designed in Phase I. The form of the implementation should be an emulation, but a well constructed simulation is also acceptable. The emulation or simulation must clearly show all the functionality and flexilibity design in Phase I as well as to provide a realistic estimate of required power consumption and associated battery life. Also, a full VLSI chip prototype will be developed and demonstrated in both civilian and military environments and systems. It is required that at least 100 nodes be implemented and demonstrated.
Phase III: The civilian applications include (but are not limited to) the networking of sensors that monitor oil/natural gas pipelines and processing facilities, electric power lines and power generation plants (both nuclear and conventional fired), airport runways and terminal facilities, water treatment plants and reservoirs, as well as large disturbed commercial manufacturing facilities.
The military applications include (but are not limited to) providing networked sensor communications for forward areas (brigade and forward) as well as munitions mine field deployment, monitoring and control.
REFERENCES:

1) Shil, E., et. al., "Physical Layer Driven Algorithm and Pprototocl Design for Energy Efficient Wireless Sensor Networks", Proceedings of MOBICOM 2001, Rome, italy, July 2001.

2) Shil, E., et. al., "Energy Efficient Link Layer for Wireless Micro-Sensor Networks", Proc. Workshop on VLSI 2001, Orlando, FL. April 2001.

3) Heinzelman, et. al., "Energy Efficient Routing Protocols for Wireless Micro-Sensor Networks", Hawaii International Conference on System Science, January 2000.

In military networks, this technology will be used in planning which will model, predict or forecast the network infrastructure necessary to provide QoS for the deployment and conduct of military operations. Once military operations are active, this technology can be used to monitor, predict, forecast, and tailor changes to the communications network in support of the commander need for QoS for the military multimedia applications.

This Phase III technology development could be used to support the military and commercial applications adopted by the Federal Government's Homeland Security effort.

1) Forecasting Network Performance to Support Dynamic Scheduling Using the Network Weather Service, Rick Wolski, Proceedings of the 6th International Symposium on High Performance Distributed Computing, p 316-325.

a. Military Application: The resultant analog-to-digital converter (ADC) technology could be inserted into future JTRS radio family members as a pre-planned product improvement. This technology could also be directly applicable to any communication system for Homeland Security.

1) JTRS Operational Requirements Document (ORD)

KEYWORDS: ADC - Analog to Digital Converter, Direct Digitization, JTRS