1 / 33

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.

vilina
Download Presentation

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

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  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

More Related