Relative-time inversions in the Labrador Sea acoustic tomography experiment.

One-year long travel-time data from the second deployment period of the Labrador Sea acoustic tomography experiment are analyzed, using a relative-time matched-peak approach, in order to invert for the sound-speed field and simultaneously solve for an unknown travel-time offset. From the relative-time inversions oceanographic information in terms of vertically averaged temperatures are deduced, yielding satisfactory matching with respect to available independent observations. The estimated offsets can be attributed to differential clock drifts, showing a clear parabolic behaviour over the course of the experiment, reaching maximum deviations from linear clock drift corrections (end-point calibrations) of the order of 50 ms. By applying the estimated second-order corrections to the travel-time data, absolute-time matched-peak inversions can then be performed. The used matched-peak approach accounts for the non-linear behaviour of travel times, which is due to the seasonally variable acoustic propagation conditions in the probed region, and turns out to be an appropriate tool in dealing with unknown travel-time offsets

Multipurpose acoustic networks in the integrated arctic ocean observing system

The dramatic reduction of sea ice in the Arctic Ocean will increase human activities in the coming years. This activity will be driven by increased demand for energy and the marine resources of an Arctic Ocean accessible to ships. Oil and gas exploration, fisheries, mineral extraction, marine transportation, research and development, tourism, and search and rescue will increase the pressure on the vulnerable Arctic environment. Technologies that allow synoptic in situ observations year-round are needed to monitor and forecast changes in the Arctic atmosphere-ice-ocean system at daily, seasonal, annual, and decadal scales. These data can inform and enable both sustainable development and enforcement of international Arctic agreements and treaties, while protecting this critical environment. In this paper, we discuss multipurpose acoustic networks, including subsea cable components, in the Arctic. These networks provide communication, power, underwater and under-ice navigation, passive monitoring of ambient sound (ice, seismic, biologic, and anthropogenic), and acoustic remote sensing (tomography and thermometry), supporting and complementing data collection from platforms, moorings, and vehicles. We support the development and implementation of regional to basin-wide acoustic networks as an integral component of a multidisciplinary in situ Arctic Ocean observatory

Acoustic thermometry of the western Mediterranean basin

Ocean acoustic tomography is used to obtain heat-content estimates for the western Mediterranean basin. Travel-time data from 13 tomography sections of the Thetis-2 experiment (January–October 1994) are analyzed with a matched-peak inversion approach. The underlying analysis involves the use of peak arrivals and nonlinear model relations between travel-time and sound-speed variations. Slice inversion results are combined with temperature covariance functions for the western Mediterranean to obtain heat-content estimates for the basin. These estimates compare favorably with ECMWF data over the nine-month period of the Thetis-2 experiment. Furthermore, estimates for the basin-average temperature of the western Mediterranean deep water are obtained. © 2004 Acoustical Society of America