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本文针对温度差异对沉积物的声学特性的影响,研究不同温度下沉积物的频谱特征规律。把南海深海沉积物的人工样品置于温控环境中,采集经历沉积物的超声信号,对其进行快速傅里叶变换获得频谱特征,分别从主频漂移、主频幅值、主频频宽、接收能量等方面归纳出温度影响下的海底沉积物超声信号的频谱特征规律:如温度变化影响频谱特征,但可重复性低;温度增加使沉积物对声信号的衰减增大;频宽与频率幅值呈负相关,但温度-幅值的关系明显于温度-频宽的关系。因此,温度改变导致沉积物超声信号频谱的规律性变化。 相似文献
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投弃式海流剖面测量仪测量原理研究 总被引:1,自引:0,他引:1
根据投弃式海流剖面测量仪的测量原理建立了二维海流运动感生电场离散和连续模型,通过模型推导得到了海流与感生电场间的关系公式。通过对海流感生电磁场的分析,对海流测量的基本方法进行了研究,通过感生电磁场的量级的计算,确定了投弃式海流剖面测量仪研究的主要方向和关键技术。 相似文献
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琼州海峡夏季三塘潮流谱分析和余流特征研究 总被引:3,自引:0,他引:3
无论潮流矢量是反时针旋转(f>0)还是顺时针旋转(f<0),全日潮谱峰都高于半日潮谱峰。2个半日潮周期分别为12、12.4h;2个日潮周期分别为23.9和25.8h;在半日潮和全日潮分量中,反时针分量是主要的:顺时针的半日潮能谱只有反时针的84%;顺时针的日潮能谱只有反时针的65%;浅水分潮6.2、8h和超过24h的3、4.2和5.5d等也有明显表现,但是都未通过显著性检验;夏季余流流速在5~10cm/s范围内变化,方向以南偏西为主。造成这种现象的首要的因素是夏季琼州海峡水交换基本态势和三塘附近海底地形,风对流向变化也有重要影响。 相似文献
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用锚定、座底声学多普勒海流剖面仪(ADCP),对白龙尾开阔水域进行为期1a的分层海流观测,通过最大熵谱分析方法,得出结论:1)日分潮O1,K1和半日分潮M2,S2是白龙尾主要分潮流,半日潮流能量大于日潮流能量;2)在半日潮和全日潮分量中,逆时针运动(f0)是主要的,并从潮波旋转形态方面给予解释;3)周期为6h左右的浅水分潮,在底层通过显著性检验,表明近底摩擦是浅水分潮生成的主要机制;4)在f0情况下,周期超过3d的长周期运动(余流)有3个,其中8.3d的长周期运动,在表、中和底层都通过显著性检验,5.2d在中层和底层通过显著性检验,认为主要是潮余流引起的。 相似文献
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基于南海北部浮标和潜标的声学多普勒流速剖面仪(ADCP)数据,通过一套几何算法计算了台风海鸥(1415)期间ADCP的空间变化和流速误差,并进行数据校正。浮标上,台风过后ADCP的水平位移最大可达2.61 km,水平流速误差最大可达0.27 m/s,垂向流速误差最大仅为5×10-4 m/s;温跃层流速校正值在台风过后显著大于流速测值,这表明水平校正对于温跃层流速的质量控制很重要。潜标上,ADCP最大垂向位移增量为179 m,最大绳子倾角为35°,最大水平位移为1.5 km; ADCP水平流速误差和倾角误差都很小,在数据校正中可忽略不计,但对台风过后中层流速的垂向校正不能忽略。 相似文献
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David Hurther Peter D. Thorne Mickaël Bricault Ulrich Lemmin Jean-Marc Barnoud 《Coastal Engineering》2011
The use of acoustics to measure sediment transport boundary layer processes has gained increasing acceptance over the past two decades. This has occurred through the development of increasingly sophisticated measuring systems and theoretical developments, which have enabled flow and suspended sediment parameters to be obtained from acoustic data with a high degree of accuracy. Until relatively recently, separate acoustic systems were used to measure flow and suspended sediment concentration. Over the past few years, however, the technology has become sufficiently advanced so that flow and sediment measurements can be integrated into a single system. This integration provides, quasi-instantaneous, non-intrusive, co-located, high temporal-spatial resolution measurements of benthic flow and sediment processes. Here the development of such an instrument, the Acoustic Concentration and Velocity Profiler (ACVP) is described. The theory underpinning its application is outlined, new approaches to velocity de-aliasing and suspended sediment inversion instabilities using multi-frequency capabilities are presented and the application of the system to sediment transport processes over a sandy ripple bed is illustrated. The observations clearly show the value of such instrumentation for studying the dynamical interaction between the bed, the flow and the sediments at and within the bottom boundary layer. 相似文献
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