Real-Time Beyond the Horizon Vessel Detection

Slides:

Advertisements

Similar presentations

Coastal Ocean Impact on Hurricane Irene (2011) Intensity 1. BACKGROUND 2. HYPOTHESIS 3. OBSERVATIONS & MODEL 6. FUTURE WORK5. CONCLUSIONS 4. RESULTS Acknowledgements:

Advertisements

What happens when the ship hits the fan. By Laura Harrison June 12 th, 2006 Geography 163.

Success Stories – Making a Difference Optimizing HF Radar for SAR using USCG Surface Drifters Art Allen U.S. Coast Guard Josh Kohut, Scott Glenn Rutgers.

Success Stories – Making a Difference Optimizing HF Radar for SAR using USCG Surface Drifters Art Allen U.S. Coast Guard Josh Kohut, Scott Glenn Rutgers.

Cape Cod to Cape Hatteras: ~1000 km Coastline Results from the Mid Atlantic High Frequency Radar Network Hugh Roarty, Ethan Handel, Erick Rivera, Josh.

Integrated Ocean Observing System (IOOS) Demonstration Project Ports of Los Angeles/Long Beach Julie Thomas Southern California Coastal Ocean Observing.

Remote Sensing: John Wilkin Active microwave systems (4) Coastal HF Radar IMCS Building Room 214C ext 251 Dunes of sand.

Welcome MACOORA Annual Meeting October 22-23, 2008 Fall River, Massachusetts Carolyn Thoroughgood.

GCOOS HF Radar Gap Analysis Version 1.0, 27 June 2008 Key Authors –Stephan Howden, USM –Nick Shay, UM –Ann Jochens, TAMU Consulted with –GCOOS-RA Board.

Remote Sensing: John Wilkin Active microwave systems Coastal HF Radar IMCS Building Room 214C ph: Dunes of sand and seaweed,

Development of a Dual-Use Over-The Horizon Radar Network for Monitoring Ocean Currents and Ship Traffic in the Exclusive Economic Zone Scott M. Glenn Coastal.

National Center for Secure and Resilient Maritime Commerce and Coastal Environments (CSR) CSR Scott Glenn, Hugh Roarty Rutgers University Washington DC.

SeaSonde Overview.

US IOOS ® Contributions to Maritime Security Integrated Ocean Observing System Program Office Department of Commerce, NOAA Suzanne Skelley Deputy Director.

Persistence Surveillance Objectives Protect U.S. resources, including fisheries, habitats and protected species Monitor the state of ocean resources Combine.

The Gulf of Maine Ocean Observing System. Technical Program Real time monitoring and forecasts of: Weather - surface ocean winds, air temperature, visibility.

Using Ocean Observing Systems & Real Time Data to monitor and clean up Oil Spills.

The TIDDBIT HF Doppler Radar G. Crowley and F. Rodrigues

Cape Cod Cape Hatteras NJ MA CT VA DE NY NC RI MD PA M ID - A TLANTIC R EGIONAL A SSOCIATION C OASTAL O CEAN O BSERVING S YSTEM 1000 km Cape to Cape RAISING.

CALYPSO Seminar, 29 th of August of 2013 “Recent advances in the application of SeaSonde HF Radar technology to improve Operational Oceanography capacity”

National High Frequency Radar Network Jack Harlan, Ph. D. NOAA IOOS Program Office Project Manager: HF Radar DHS Training 21 Apr 2010 Washington, DC.

Graphic courtesy NOAA / PMEL / Center for Tsunami Research Pacific Northwest Waters Gateway to Our Future Communication through the NANOOS Visualization.

. Tracking Uncertainty in Search and Rescue Planning Art Allen U.S. Coast Guard Office of Search and Rescue

Ligurian Sea Mid-Atlantic Bight Results from the Mid Atlantic High Frequency Radar Network Radar Network Hugh Roarty, Scott Glenn, Josh Kohut, Erick Rivera,

CODAR Ben Kravitz September 29, Outline What is CODAR? Doppler shift Bragg scatter How CODAR works What CODAR can tell us.

U.S. IOOS ® HF Radar Network 10 Years of Experience Measuring Ocean Surface Currents Jack Harlan, Ph.D. U.S. Integrated Ocean Observing System (IOOS ®

Surface Current Mapping with High Frequency RADAR.

L. K. Shay 1, J. Martinez-Pedraja 1, B. K. Haus 1, Brad Parks 1, Peter Vertes 1, Lew Gramer 2, and J. Brewster 1 1 Division of Meteorology and Physical.

InvestigatorAffiliationInvestigatorAffiliation A. AllenU.S. Coast GuardL. AtkinsonOld Dominion University A. F. BlumbergStevens Institute of Technology.

Surface Current Mapping in the Lower Chesapeake Bay INTRODUCTION High frequency RADAR antennas are used to observe the surface circulation patterns in.

Ocean Wave and Current Radars By Laura Elston. Our earth is a very aqueous environment with nearly three quarters of it covered by ocean. So how do we.

New Project to Meet Surveillance Requirements in the Remote Pacific Persistence Surveillance Objectives: Protect U.S. resources, including fisheries, habitats.

AWIPS-2 HF Radar Sea-Surface Current Product By Ross Van Til Contributions by: Nicole Kurkowski, OS&T Dr. Pablo Santos, WFO Miami Dr. Jack Harlan, NOAA.

Application of Radial and Elliptical Surface Current Measurements to Better Resolve Coastal Features  Robert K. Forney, Hugh Roarty, Scott Glenn 

Ocean Surface Current Observations in PWS Carter Ohlmann Institute for Computational Earth System Science, University of California, Santa Barbara, CA.

Mr. Robert Forney Dr. Hugh Roarty Dr. Scott Glenn Measuring Waves with a Compact HF Radar MTS/IEEE OCEANS15 October 2015 Washington DC.

L. K. (Nick) Shay, J. Martinez-Pedraja and M. Archer Department of Ocean Sciences, RSMAS To improve our understanding of surface processes and their linkages.

New Technology Developments for Increased Maritime Domain Awareness In the Chukchi Sea USCG Debrief Juneau, AK July 27, 2012 Presented by Hank Statscewich.

CODAR Surface Current Maps Improve Coast Guard Search And Rescue Nearest Coastal Site CODAR Currents SLDMB Drifter SAROPS NowSAROPS w/ HFR Surface Currents.

Commercial Space-based Synthetic Aperture Radar (SAR) Application to Maritime Domain Awareness John Stastny SPAWAR Systems Center Pacific Phone:

Surface Current Mapping in the Lower Chesapeake Bay INTRODUCTION High frequency RADAR antennas are used to observe the surface circulation patterns in.

CASE #3: Floating Away The Situation: While entering New York Harbor, several boxes of rubber ducks fell off their cargo ship. Using the data provided,

QA/QC Methods for 13 MHz Brant Beach (BRNT) Test Case

Validation of an ultra high frequency radar (River sonde) for current mapping in the urbanized Hudson River estuary 2010 summer research institute at.

Results from the Mid Atlantic High Frequency Radar Network

Evaluation of Three Antenna Pattern Measurements for a 25 MHz SeaSonde

National High Frequency Radar Network

Mid-Atlantic Blue Ocean Economy 2030

MARACOOS High Frequency Radar Network Operations

Bistatic Systems: Preparing for Multistatic

Application of 13 MHz SeaSonde Systems for Vessel Detection

OCG High Frequency Radar

Hugh Roarty, Michael Smith, Ethan Handel and Scott Glenn

Atmospheric Sciences 370 Observing Systems Winter 2018

Robert K. Forney, Hugh Roarty, Scott Glenn March 5th, 2015

Colin Evans, Hugh Roarty, Scott Glenn, Josh Kohut

Quality Assurance Measures for High Frequency Radar Systems

AUX Conference Rescue 21 Brief

High-Frequency Radar Surface Currents in Alaska: Bering Strait

Analysis of the Wind Resource off New Jersey for Offshore Wind Energy Development Hugh Roarty, Joe Riscica, Laura Palamara, Louis Bowers, Greg Seroka,

HF Radar Systems Engineering Plan

Recognizing First and Second Order Features

October 27, 2011 New Brunswick, NJ

LCDR George Wright, USN OC 3570 – Winter 2008 Friday, March 14th 2008

An Ocean Current Monitoring System for Coastal New Jersey

Offshore Atmospheric and Ocean Monitoring to Support DEEPWATERwind’s Offshore Wind Energy Project Development and Operations Rich Dunk, Ph.D.,

A Multi-static HF Radar Network for the

Observing the Ocean from the Rutgers University “COOL Room”

Coastal Ocean Dynamics Radar (CODAR) Mapping of

Southern California Coastal Ocean Observing System (SCCOOS) HF RADAR Network “SCCOOS brings together coastal observations in the Southern California Bight.

Presentation transcript:

Real-Time Beyond the Horizon Vessel Detection Hugh J. Roarty Michael Smith Scott M. Glenn Donald E. Barrick

Talk Outline Introduction to RUCOOL Introduction of HF radar Application of HF radar for Search and Rescue (SAR) Use of HF radar for vessel detection Real-time results for NY Harbor

Coastal Ocean Observation Lab Rutgers University Coastal Ocean Observation Lab Satellite Data Acquisition Stations CODAR Network Glider Fleet 3-D Forecasts

Introduction to hf Radar

CODAR Compact HF Radar Antennas 25 MHz 13 MHz 5 MHz Combined Transmitter & Receiver Separate Transmitter & Receiver FMCW Doppler Radar Average Power 50 watts

Standard CODAR Shore Site: Shed, Enclosure, Tx/Rx, Comms, Power, GPS, AIS monitor computer & external hard drive A.C. unit UPS system transmitter receiver Two lines of Communication Shed Enclosure Lightning Protection

Surface Current Mapping Capability 25 MHz Radar l: 12 m Ocean l: 6 m Range: 30 km Resolution: 1 km 13 MHz Radar l: 23 m Ocean l: 12 m Range: 80 km Resolution: 3 km 05 MHz Radar l: 60m Ocean l: 30 m Range: 180 km Resolution: 6 km

1000 km Alongshore Length Scale Mid-Atlantic Bight HF Radar Network 1000 km Alongshore Length Scale Mid-Atlantic HF Radar Network 16 Long-Range CODARs 8 Medium-Range CODARs 17 Short-Range CODARs 41 Total Triple Nested & Multistatic

Winter Storm Nemo February 9, 2013

Application of hf Radar to Search and Rescue

Transition Success Stories – Making a Difference Optimizing HF Radar for SAR using USCG Surface Drifters Art Allen U.S. Coast Guard Scott Glenn Rutgers University Mid-Atlantic Regional Association Coastal Ocean Observing System

HF Radar (Measurements) SAROPS Test Case 5000 Virtual Drifters + 1 Real Drifter (Black Line): Search Area After 96 Hours 154 km 100 km HYCOM (Low Conf) 48 hours 232 km 123 km HYCOM (Ocean model) Search Area: 36,000 km2 HF Radar (Measurements) Search Area: 12,000 km2

hf Radar for Vessel Detection

Vessel Detection Capability 25 MHz Range: 11 nmi Height >10 ft 13 MHz Range: 43 nmi Size: >19 ft 05 MHz Range: 65 nmi Size: >49 ft

Doppler Spectra from all Range Cells with Detection Threshold above Background Applied Doppler Frequency (Target Speed) Range Bragg Waves Fixed Objects & Direct Signals Vessel

Range (km) Radial Velocity (m/s) Bearing (°CWN) Step 1 Raw Detections From each HFR: Radial Velocity (most accurate) Range Bearing (least accurate) Range (km) Radial Velocity (m/s) Bearing (°CWN)

The Center for Secure and Resilient Maritime Commerce (CSR) DHS Center of Excellence for Port Security 10 Institutions – Maritime Domain Awareness & Resiliency Maritime Domain Awareness Approach – Dual Use Technologies Demonstrate Nested Vessel Detection Global > Approaches > Port University of Miami – Global Satellite Coverage, Visible & Microwave Rutgers University – Over-the-Horizon Compact High Frequency Radar Networks Stevens Institute of Technology – Local High-Resolution Optics & Shallow Underwater Acoustics

NY HARBOR RECENT RESULTS

GPS Track YM Los Angeles 19

Pepper Plot Detections on a Map 20

Association of GPS with Detections 21

NY HARBOR 2012 RESULTS

Detections Overlaid on AIS June 11, 2012 06:00-07:00 GMT Median Background 512 pt. FFT 14 dB SNR detection threshold 13 vessels on AIS

Detections Overlaid on AIS June 11, 2012 07:00-08:00 GMT Median Background 512 pt. FFT 14 dB SNR detection threshold 12 vessels on AIS

HF Radar Detections NOT on AIS 31% of HF Radar Detections NOT on AIS Approaches to New York Harbor 16 Vessels per Hour in HFR 5 Vessels NOT on AIS

Calusa Coast Test Case

Location Error (km) 5 10 15 Intersecting Ranges

National hf Radar network

NOAA National Network: Existing Sites Alaska - 3 NOAA National Network: Existing Sites Puerto Rico - 2 CONUS - 104 Hawaii - 3

NOAA National Network: Proposed Sites Alaska - 17 NOAA National Network: Proposed Sites Puerto Rico - 20 CONUS - 262 Pacific Islands - 21

Conclusions Next Steps HF radar being used by Coast Guard for Search and Rescue Can also be used for Maritime Domain Awareness Next Steps Utilize bistatic data Develop tracker for detections Questions?