AWACS/SW06 Sea Tests: RV Endeavor Cruise # August – 10 September, 2006 Phil Abbot, OASIS Inc Jim Lynch and Glen Gawarkiewicz, WHOI John Joseph, NPS 31 January 2007 ONR Progress SW06 Meeting San Diego, CA
Objectives for SW06 Sea Tests Build and test components and algorithms for an AWACS of quiet targets operating in complex, littoral, shallow water environments Conduct high resolution acoustic measurements in the variable shelfbreak environment Evaluate effects of the environment on acoustic propagation uncertainty and detection characteristics –Horizontal isotropy and invariance –Spatial-temporal dependence, frequency dependence Use adaptive sampling techniques to reduce uncertainty in the ocean and acoustic fields
OMAS Transmission Summary: 550 – 650 Hz and 800 – 1000 Hz 3 x 2 sec, HFM Slides, 1 min rep rate, 700 – 1,000 Hz CW Depths: 35 – 60 m 9 Runs, 6 – 8 hrs/run Tracking/TL Measured Via Multiple Sonobuoys (LBL) Extensive Spatial Diversity OMAS -- Key Workhorse in AWACS/SW06 For TL and Surrogate Target Detection
OMAS Measured Tracks During AWACS/SW nmi OMAS Tracks based on Objective Maps and Ocean Adaptive Sampling of Environmental Keys (cross-shelf position, cold pool duct, mixed layer depth)
Temperature field objective map from 12 th Scanfish survey (provided by A. Shcherbina, WHOI). Contour plot at the bottom is from 40 m depth. Mixed layer depth considerably deeper off shore Shelfbreak front extends seaward over upper slope Shelfbreak front moved seaward after TS Ernesto 80 m isobath
AWACS/SW06 TL Example: Horizontal Isotropy and Translational Invariance Tests OMAS 1 OMAS nmi Shelfbreak Front – Obj. Map TL means robustly constant except where interacting with Shelfbreak Front. SB Front R = 7.5 km, f=900 Hz TL R = 7.5 km, f=900 Hz
Sonobuoy Detection of OMAS 0˚ 360˚ Bearing 0˚ 360˚ Bearing Frequency Bin Energy Detect BTR Post Processing Peak Energy Detection OMAS Scissorgram Time (min) OMAS Tones OMAS FM Sweeps OMAS Track R/V Endeavor Track
Analyses Plans/Needs Analyses/Papers in collaboration with AWAC PIs, and Others? –Horizontal Isotropy/Invariance –Propagation Through/Along SB Front –Propagation to WHOI Fixed Receivers Needs –Internal Wave Field Observations During Acoustic Tests –Sea Surface Observations –Bottom Characterization in Area, Including Improved Geo-acoustic Models –Ocean Characterization with Scanfish –Fixed Receiver Time Series –More? Cruise Reports Bundled and Available Upon Request
Backups
Challenges Safely deploy/recover AUVs w/towed arrays in 4-6 foot seas (<20 knots wind speed) Autonomously detect targets, then Pass information though the ACOMMS link Develop vehicle command/control methods based on adaptive sampling Explore limits of signal processing, with emphasis placed on dynamic array control
Summary of AWACS/SW06 Built and tested components and algorithms for AWACS system Conducted high resolution oceanographic and acoustic measurements in the New Jersey shallow water environment –12 Scanfish surveys (>160 hrs) characterizing the Shelfbreak Front variability –9 OMAS Acoustic tests (>60 hrs) characterizing the effects of the SB front on acoustic propagation, including detection performance Performed Adaptive Sampling to resolve SB Front and exploited it for improved acoustic transmissions. Objective maps, combined with Data Assimilation at shore, provided sampling ideas –Demonstrated sensitivity to source/receiver depth (6 dB improvement) –Transmissions along/through the front Quantified regions of TL uncertainty (scales for horizontal isotropy and translational invariance) Early Nov. tests planned to deploy TAs off the glider and REMUS vehicles in SW near the Vineyard
Slocum Glider w/OASIS Towed Array Dummy TA in HI (May 06); OTA Calibrated in Dodge Pond, and Integrated with Glider at Webb and WHOI REMUS in Aug. 06
Autonomous Wide Aperture Cluster for Surveillance (AWACS) Concept
Adaptive Sampling “Maximum Bearings”- An adaptive survey was run with 4 separate transects through a single point at the front to get 8 separate bearings for comparisons with circular OMAS trajectory “Streamwise Coordinates”- One adaptive survey was run oriented along the axis of the front, to ensure that any sharp curvature of the front downstream of the release point of the sonobuoys was accounted for
AWACS Towed Arrays WHOI –WTA 32 Hydrophone, 16 channels Cut to 1.0 kHz (P = /2) 24 Bit ADC, Variable Sample Rate Data stored on hard drive (120 GB?) –PTA 12 hydrophone, 3x2 channels Cut to 1.0 KHz Data stored on 3 (x 2 channels) Sony Mini-Disk Recorders OASIS (OTA) –32 Hydrophone, 16 channels –Cut to 1.0 kHz (P = /2) –24 Bit ADC, Selectable Sample Rate –Data stored on 3 Compact Flash Disks (3x4 GB) or Hard Drive (30 GB) –1.1” Diameter, Gel-Filled Hose –L(Array Section) = 12.9 m, L(Leader) = 9.4 m
SLOCUM Glider, OASIS Towed Array (OTA) and OMAS on the Endeavor During In-Air Shakedown Glider Towed Dummy Array in HI, May 06. OTA Calibrated in Dodge Pond June 06, then Integrated with Glider at Webb and WHOI REMUS in Aug. 06
OASIS TA Integration with AWACS AUVs Buoyancy Tests at Webb Integration w/REMUS at WHOI