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Quick Look at Some Advances in the Integration of Different Sensor Technologies

Quick Look at Some Advances in the Integration of Different Sensor Technologies. Carl F. Steiner - Class of ‘88 Chief Design Engineer Science Applications International Corporation (SAIC). TIGER - Triangulation Identification for Genetic Evaluation of Risks.

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Quick Look at Some Advances in the Integration of Different Sensor Technologies

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  1. Quick Look at Some Advances in the Integration of Different Sensor Technologies Carl F. Steiner - Class of ‘88 Chief Design Engineer Science Applications International Corporation (SAIC)

  2. TIGER- Triangulation Identification for Genetic Evaluation of Risks

  3. TIGER- Triangulation Identification for Genetic Evaluation of Risks • On-Chip Broad Range Polymerase Chain Reaction (PCR)

  4. TIGER- Triangulation Identification for Genetic Evaluation of Risks • On-Chip Broad Range Polymerase Chain Reaction (PCR)

  5. TIGER- Triangulation Identification for Genetic Evaluation of Risks • On-Chip Broad Range Polymerase Chain Reaction (PCR) • Fourier Transform Mass Spectrometry (FTMS)

  6. TIGER- Triangulation Identification for Genetic Evaluation of Risks • On-Chip Broad Range Polymerase Chain Reaction (PCR) • Fourier Transform Mass Spectrometry (FTMS) • Statistics (Pd, Bayesian Inference, False Positives)

  7. TIGER- Triangulation Identification for Genetic Evaluation of Risks • On-Chip Broad Range Polymerase Chain Reaction (PCR) • Fourier Transform Mass Spectrometry (FTMS) • Statistics (Pd, Bayesian Inference, False Positives) • SW, HW Interfaces

  8. Example of Different Sensor Types

  9. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency

  10. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency • Acoustic • Sonar

  11. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency • Acoustic • Sonar • Chemical, Biological, Radiological

  12. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency • Acoustic • Sonar • Chemical, Biological, Radiological • Effluent

  13. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency • Acoustic • Sonar • Chemical, Biological, Radiological • Effluent • Environmental (wind, temperature, rH, solar, TOD, location, orientation, etc.)

  14. Example of Different Sensor Types • Electro-Optical • Infrared • Hyper-spectral • LASER • Microwave • RADAR • LIDAR • Radio Frequency • Acoustic • Sonar • Chemical, Biological, Radiological • Effluent • Environmental (wind, temperature, rH, solar, TOD, location, orientation, etc.) • Magnetic (MRI, MPI, SERF, SQUIDs) • Other

  15. Some Examples of Uses Now • Polymerase Chain Reaction (PCR) • Passive Acoustic, Seismic, and Electromagnetic (PASEM) • LASER Induced Breakdown Spectroscopy • Ultraviolet Imaging • Long Wave/Short Wave Infrared Imaging • Near Infrared Imaging (NIR) • Ultrasonic Imaging • Hyper- and Multi-Spectral Imager • Staring Dual Band Infrared Arrays • LASER Interferometry • Inertial Navigation Systems (INS) • Micro Electro Mechanical Systems (MEMS and Microsensors) • Interferometric Fiber Optic Gyroscope (Sagnac Effect) • Foliage Penetrating Synthetic Aperture RADAR • Ground Penetrating RADAR • Broadband, Variable-Depth Sonar • Synthetic Aperture Sonar • Miniature and LASER Cooled Atomic Clocks

  16. Hybrid Sensor Integration

  17. Hybrid Sensor Integration • Data and Sensor Fusion Problem

  18. Hybrid Sensor Integration • Data and Sensor Fusion Problem • Kalman Filters • Bayesian Networks / Decision Trees • Apriori data base information / Adaptive Learning • Situational Awareness

  19. Hybrid Sensor Integration • Data and Sensor Fusion Problem • Kalman Filters • Bayesian Networks / Decision Trees • Apriori data base information / Adaptive Learning • Situational Awareness • Examples

  20. Hybrid Sensor Integration • Data and Sensor Fusion Problem • Kalman Filters • Bayesian Networks / Decision Trees • Apriori data base information / Adaptive Learning • Situational Awareness • Examples • Unattended Robotically Controlled Systems

  21. Hybrid Sensor Integration • Data and Sensor Fusion Problem • Kalman Filters • Bayesian Networks / Decision Trees • Apriori data base information / Adaptive Learning • Situational Awareness • Examples • Unattended Robotically Controlled Systems • Tunable Filter Multi-Spectral Camera • Autonomous Distributed Sensors • Networked Sensor Systems

  22. Hybrid Sensor Integration • Data and Sensor Fusion Problem • Kalman Filters • Bayesian Networks / Decision Trees • Apriori data base information / Adaptive Learning • Situational Awareness • Examples • Unattended Robotically Controlled Systems • Tunable Filter Multi-Spectral Camera • Autonomous Distributed Sensors • Networked Sensor Systems • Hurdles • Size, Weight, & Power • Robustness / MTTF • Cost

  23. Innovative Approaches

  24. Innovative Approaches Distributed Processing

  25. Innovative Approaches • Distributed Processing • Synergistic Advantage

  26. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking

  27. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust”

  28. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust” • Energy Harvesting & Storage

  29. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust” • Energy Harvesting & Storage • Piezoelectric & Bio-Mechanical

  30. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust” • Energy Harvesting & Storage • Piezoelectric & Bio-Mechanical • Pyroelectric

  31. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust” • Energy Harvesting & Storage • Piezoelectric & Bio-Mechanical • Pyroelectric • Nanogenerators (wind turbines, vibration)

  32. Innovative Approaches • Distributed Processing • Synergistic Advantage • Meshed Networking • “Smart Dust” • Energy Harvesting & Storage • Piezoelectric & Bio-Mechanical • Pyroelectric • Nanogenerators (wind turbines, vibration) • RF Antennae

  33. END

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