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Main Title Advances in Sensing with Security Applications [electronic resource] /
Type EBOOK
Author Byrnes, Jim.
Other Authors
Author Title of a Work
Ostheimer, Gerald.
Publisher Springer Netherlands,
Year Published 2006
Call Number ########
ISBN 9781402042959
Subjects Analytical biochemistry ; Remote sensing ; Optical pattern recognition ; Mathematics ; Computer science ; Biomedical engineering
Internet Access
Description Access URL
http://dx.doi.org/10.1007/1-4020-4295-7
Collation XIII, 367 p. online resource.
Notes
Due to license restrictions, this resource is available to EPA employees and authorized contractors only
Contents Notes
Preface. Acknowledgments.Bistatic and multistatic radar sensors for homeland security.. 1. Introduction -- 2 Definitions .-3. Bistatic essentials -- 4. Passive Coherent Location (PCL) -- 5. Multistatic radar .-6. Conclusions -- 7. Acknowlegments .-References.The Terrorist Threat and Its Implications for Sensor Technologies.1. Introduction -- 2. What is Terrorism? -- 3. General Trends in Terrorism -- 4.Significant Domestic Threats -- 5. State Sponsored Terrorism -- 6. Future Threats -- 7. Preventions Efforts The Role of Sensors -- 8. Improving Sensors -- 9. Conclusions -- References. Advances in sensors; the lessons from Neurosciences.1. Energies that affect earth living organisms survival -- 2. The emergence of a nervous system. 3. Neurons as excitable cells -- 4. Sensory neurons -- 5. Sensory transduction -- 6. Molecules of sensory transduction -- 7. Hearing system and mechanosensation -- 8. Temperature receptors -- 9. Pain receptors -- 10. Olfaction -- 11. Vision .-12. General view of the sensory systems -- References. Chemical sensors and chemical sensor systems.1. Introduction-Parameters -- 2. Fundamentals Devices; 3. Thermopiles -- 4. Kelvin Probe -- 5. Bulk Acoustic Waves -- 6. Surface Acoustic Waves -- 7. Natural and Artificial Olfaction -- 8. Optical Fibre Sensor -- 9. Surface Plasmon Resonance -- 10. Conclusions -- References. Wireless Sensor Networks for Security: Issues and Challenges.1. Introduction -- 2. Neyman-Pearson Detection -- 3. Breach Probability Analysis [30].-4. Data Processing Architecture for Target Tracking -- 5. Maximum Mutual Information Based Sensor Selection Algorithm -- 6. Simulation Results -- 7. Conclusion.-References. Internet-Scale Chemical Sensing.1. Introduction -- 2. Chemical Sensing and Biosensing -- 3. Miniaturised Analytical Instruments - Lab on a Chip Devices -- 4. Analytical Device Hierarchy.-5. Networking Options.-6. Integrating Chemical Sensors and Biosensors with Wireless Networks -- 7. Scale-up Issues for Densely Distributed Analytical Devices -- 8. Chemo- & Bio-warfare Agents -- 9. Sensor communities and group behaviour -- 10. pHealth -- 11. Conclusions -- References. Data analysis for chemical sensor arrays..1. Feature extraction.-2. Data Pre-processing: Scaling -- 3. Normalization.-4 -- Multivariate data exploration -- 5. Principal Component Analysis -- 6. Supervised Classification -- 7. Linear Discrimination -- 8. Application to the investigation of Chemical Sensors properties -- 9. Conclusions -- References. Fundamentals of Tomography and Radar. 1. Introduction.-2. Imaging and Resolution -- 3. Tomographic Imaging -- 4. The Projection Slice Theorem -- 5. Tomography of Moving Targets -- 6. Applications -- 7. Automatic Target Recognition -- 8. Bandwidth Extrapolation -- 9. Target-matched Illumination -- 10. Conclusion.-11. Acknowledgements -- References. Remote Sensing using Space Based Radar.. 1. Introduction -- 2. Geometry -- 3. Range Foldover and Earth's Rotation -- 4. Application of STAP for SBR .-5. Orthogonal Pulsing Scheme -- References. Continuous wave radars-monostatic, multistatic and network .1.Introduction -- 2. Radar fundamentals -- 3. Linear Frequency Modulated Continuous Wave Radar -- 4. Noise Radar -- 5. Noise radar range equation -- 6. Bi-static and multi-static continuous wave radars -- 7. Target identification in continuous wave radars.-References. Terahertz Imaging, Millimeter-Wave Radar. 1. Introduction -- 2. Atmospheric Limitations -- 3. Millimeter-Wave and Terahertz Sources of Radiation.-4. Millimeter-Wave and Terahertz Detectors and Receivers -- 5. Millimeter-Wave and Terahertz Optics.-6. Millimeter-Wave and Terahertz Systems -- 7. Summary -- References. Sensor Management for Radar: A Tutorial; 1. Introduction -- 2. Radar Fundamentals -- 3. Sensor Management Overview -- 4. Theory of Waveform Libraries.-5. Sensor scheduling simulations and results -- References. Waveform Design, Range CFAR and Target Recognition. 1. Introduction -- 2. Combination of LFMCW and FSK modulation principles for automotive radar systems -- Automotive Radar Network Based On 77GHz FMCW Sensors -- 4. Range CFAR Techniques -- 5. Conclusion.-References. Tomography of Moving Targets (TMT) for Security and Surveillance. . 1.Introduction -- 2. Tomography Concept and Framework .-3. Bistatic Geometry and Observables .-4. Matched Filter Processing (MFP) -- 5. TMT Netted Radar System.-6. TMT MFP Simulation -- 7. Detection Perfomance.-8. Summary -- 9. Acknowledgements -- References. Near Infrared Imaging and Spectroscopy for Brain Activity Monitoring..1. Introduction -- 2. NIR Imaging and Spectroscopy Systems -- 3. Hemodynamic Response -- 4. Neuronal Response -- 5. Human Subject Studies -- 6. Concluding Remarks and Future Directions.-References. Topic Index. The chapters in this volume were presented at the July 2005NATO Advanced Study Institute on Advances in Sensing with Security App- cations. The conference was held at the beautiful Il Ciocco resort near Lucca, in the glorious Tuscany region of northern Italy. Once again we gathered at this idyllic spot to explore and extend the reciprocity between mathematics and engineering. The dynamic interaction - tween world-renowned scientists from the usually disparate communities of pure mathematicians and applied scientists which occurred at our six previous ASI's continued at this meeting. The fusion of basic ideas in mathematics, biology, and chemistry with ongoing improvements in hardware and computation o?ers the promise of much more sophisticated and accurate sensing capabilities than c- rently exist. Coupled with the dramatic rise in the need for surveillance in innumerable aspects of our daily lives, brought about by hostile acts deemed unimaginable only a few short years ago, the time was right for scientists in the diverse areas of sensing and security to join together in a concerted e?ort to combat the new brands of terrorism. This ASI was one important initial step. To encompass the diverse nature of the s- ject and the varied backgrounds of the anticipated participants, the ASI was divided into three broadly de?ned but interrelated areas: the - creasing need for fast and accurate sensing, the scienti?c underpinnings of the ongoing revolution in sensing, and speci?c sensing algorithms and techniques. The ASI brought together world leaders from academia, government, andindustry,withextensivemultidisciplinarybackgroundsevidencedby theirresearchandparticipationinnumerousworkshopsandconferences.