As part of the modeling effort in the Acoustic Thermometry of Ocean Climate (ATOC) project, the influence of mesoscale, gyrescale and seasonal ocean variability on three-dimensional (3D) acoustic ray paths from the planned Hawaii to Monterey site is investigated. Ray paths and signal arrival structure over a two year period are simulated at a six-day interval using a 3D ray-based acoustic model. The input sound speed fields are interpolated from gridded (1/4 degree, 20 level) temperature and salinity output data from the Semtner-Chervin eddy-resolving Parallel Ocean Climate Model. Based on the simulated acoustic multipath arrival structure, the issues of stability and travel time variability are addressed. Bottom topography in the Moonless Mountains region is found to have occasional mild effects on steeper rays. Arrival structure is found to be strongly dependent on depth and quasi-stable over time with a 0.6 correlation between arrival patterns at different times. Travel time variability estimates are 0.42 s rms for steep rays, due to a combination of seasonal and mesoscale ocean variability, and 0.28 s rms for near-axial rays, due primarily to seasonal variability.
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机译:作为海洋气候声波测温(ATOC)项目建模工作的一部分,研究了中尺度,回旋尺度和季节性海洋变化对从计划的夏威夷到蒙特雷站点的三维(3D)声线路径的影响。使用基于3D射线的声学模型,每隔六天模拟一次两年内的射线路径和信号到达结构。输入声速场是根据来自Semtner-Chervin涡旋解析平行海洋气候模型的网格化温度(1/4度,20级)和盐度输出数据进行插值的。基于模拟的声学多径到达结构,解决了稳定性和传播时间可变性的问题。发现无月山脉地区的底部地形偶尔会对陡峭的射线产生轻微的影响。发现到达结构在时间上强烈依赖于深度和准稳定,并且在不同时间到达模式之间具有0.6的相关性。由于季节性和中尺度海洋变率的结合,对于陡峭的射线,旅行时间变异性估计为0.42 s rms,而由于主要是季节性的变化,对于近轴射线,传播时间变异性的估计为0.28 s rms。
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