The Unmanned Port Security Vessel

1. The Unmanned Port Security Vessel: A Multi-Sensor Autonomous System for Maritime and Port Security Brian Bingham (University of Hawaii)Hanumant Singh (Woods Hole Oceanographic Institution)Richard Camilli (Woods Hole Oceanographic Institution)

2. The Unmanned Port Security Vessel • Port response and recovery • Infrastructure and channel inspection • Change detection • Threat assessment • First Responder Support • Getting more ‘bootson the ground’ • Small boat harborsurveillance • Multidisciplinary, Multi-Institutional Science and Technology Competition

3. UPSV Programmatic Background • Multidisciplinary, Multi-Institutional Science and Technology Competition (2009) • Topic Areas: Multiple sensor integration, and Port systems resilience • “Effectively develop and integrate multiple sensors and intelligent systems from disparate sources and multiple scales.” • Requirements: • “High quality scientific research” or “Cutting-edge research program” • AND • “Adding value to DHS an its customers” • Response: Overarching Research Ideas • The role of unmanned systems in port/harbor security • Supervisory control and operator-in-the-loop autonomy • In-situ sensing and imaging. • “Data fusion” for maritime remote sensing: “Putting it on the chart”

4. Research and Development • Real-time environmental monitoring, autonomous change detection • In-situ marine chemical sensing • Robotic mapping • Supervisory control andHuman-robot interaction

5. Research and Development • Prototype platform • Sensor integration • Data and information delivery • Timeline: Hawaii Demo. 2 Hawaii Demo. 1 Year 1 Year 2 Year 2 East CoastDemo.

6. Schedule Progress

7. Schedule Forecast

8. Schedule Forecast Cont’d

9. State of the Project • Phase I Complete (4/15/2010) • Phase II initiated (7/1/2010) • Platform Development • Successful field trials of initial prototype • Implementation of real-time supervisory command and control software • Connections with DHS Mission • Working with USCG (Districts 1 and 14) and USCG R&D Center • Collaboration with Civil Support Teams • Collaboration with WHOI, ALERT and Stevens Institute of Technology

10. Field Trials • April, 2010: Remote-control testing, Keehi Lagoon • September, 2010: Software-control/archiving testing, Keehi Lagoon • December, 2010: Feedback control testing, Makai Research Pier

12. First Mapping Survey: Keehi Lagoon

14. Supervisory Control

15. OIL FLOW RATE AND FATE Testimony to the National Commission on the BP Deepwater Horizon Oil Spill and Offshore Drilling Washington DC, Sept. 27, 2010 Dr. Richard Camilli Woods Hole Oceanographic Institution Dept. of Applied Ocean Physics and Engineering Deep Submergence Laboratory

16. Robotic subsurface plume mapping using an AUV equipped with a mass spectrometer WOODS HOLE OCEANOGRAPHIC INSTITUTION DEPARTMENT OF APPLIED OCEAN PHYSICS AND ENGINEERING DEEP SUBMERGENCE LABORATORY

17. COMPOSITE MAP OF SUBSURFACE HYDROCARBON SAMPLING 5/30 – 7/14 WOODS HOLE OCEANOGRAPHIC INSTITUTION DEPARTMENT OF APPLIED OCEAN PHYSICS AND ENGINEERING DEEP SUBMERGENCE LABORATORY

18. Synergies:Transition • Working with USCG R&D Center (Don Cundy, Jack McCready, Joe Kusek) • Collaborating with National Guard Civil Support Teams (CSTs) • Leveraging DHS COE’s (CIMES, ALERT, CSR)

19. Synergies: RICC Conference • Research and Industrial Collaboration Conference (RICC)Sponsored by ALERT COE (Northeaster Univ.) • CAPT Joseph Servidio • Balancing Research and Operations • From the researcher’s perspective, what’s the primary use? • From the user’s perspectives, what transition roadblocks exist? • Can we identify “gaps” in current capabilities? • E.g., Sensor fusion, decision aids, determining intent, etc. • Mechanisms for Transition • What are the possible pathways for transition? • Traditional:University research -> Industry development -> agency acquisition • Direct:Basic Ordering Agreements (BOAs) • What is the process for setting DHS requirements?

20. Acoustic Characterization of ROV Single thruster stationary with propellers Hydrophone aft thruster Single thruster stationary without propellers Hydrophone aft thruster ROV moving forward Hydrophone aft vehicle ROV stationary Hydrophone in front ROV stationary Hydrophone aft vehicle Background noise without any motion

21. Makai Pier Testing N ---- Test 1 ---- Test 2 ---- Test 3 ---- Test 4 E

22. Synergies: Wave Glider

23. Energy Harvesting Locomotion

24. Acknowledgements • Multiple DHS Centers • CIMES • CSR • ALERT • USCG District 14 and 1 • Co-PI’s at WHOI • UHM Students

25. KITV

26. Discussion Questions • Balancing Research and Operations • From the researcher’s perspective, what’s the primary use? • E.g. Single or multi-agency shared, daily or contingencyin-port or near-coastal use? • From the user’s perspectives, what transition roadblocks exist? • E.g., Costs, risks, deployment, maintenance, training, integration, etc. • Can we identify “gaps” in current capabilities? • E.g., Sensor fusion, decision aids, determining intent, etc. • Mechanisms for Transition • Examples of successful transitions from research to reality? • What are the possible pathways for transition? • Traditional:University research -> Industry development -> agency acquisition • Direct:Basic Ordering Agreements (BOAs) • What is the process for setting DHS requirements?

27. Recent Accomplishments

31. Synergies • CSTs • RICC / ALERT • Ordnance reef • Wave Glider • R&D Center

32. Next Steps

33. Sensor Fusion • Concept • Put information “On the Chart” for first responders • Implementation • Interface with USCGEnterprise GIS