共查询到19条相似文献,搜索用时 78 毫秒
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《海洋地质前沿》2015,(9)
在海洋地震资料处理中,由于检波点空间分布不均匀造成的采集脚印现象会影响地震资料成像,特别是对双源单缆方式采集的三维地震数据影响更为明显。通过对海上某区双源单缆方式采集的天然气水合物三维地震数据采集脚印形成原因及特点的详细分析,最终分别在叠前采用子波处理、潮汐、水速校正、面元中心化方法,叠后采用频率、波数域滤波的方法压制采集脚印。通过以上关键技术的应用,提高了双源单缆方式采集的三维地震数据的信噪比和分辨率,采集脚印从时间切片和剖面上均有了明显衰减,而且实现了最大限度的保持振幅、频率、相位属性。为精细刻画、描述地质构造形态和预测天然气水合物储层分布及有利富集区带,提供可靠的地震资料。 相似文献
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《中国海洋大学学报(自然科学版)》2016,(10)
为了提高地震剖面上天然气水合物识别的可信度,以神狐海域天然气水合物钻探结果为基础,首次将剩余静校正处理技术应用于天然气水合物地震资料处理中。结果显示,在经过剩余静校正处理后的地震剖面上BSR特征清晰,反射能量强,极性反转明显。在此基础上,对比分析了过神狐海域2口水合物钻井的新老剖面品质,对比结果显示,不论是钻遇天然气水合物的SH3井,还是未钻遇天然气水合物的SH1井,经过剩余静校正处理后的新剖面成像精度得到了明显提高,剖面显示出的细微结构更加清晰,有利于天然气水合物的识别。因此,建议开展海域天然气水合物(尤其是扩散型水合物)的剩余静校正处理。 相似文献
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海上单道地震与浅地层剖面数据海浪改正处理研究 总被引:2,自引:1,他引:1
因受海面大风浪与涌浪等影响,海上单道地震与浅地层剖面数据反射同相轴常出现波浪状起伏,造成剖面反射层位错乱,分辨率与信噪比降低。根据海浪噪声与海底反射地层在横向上的相关性与变化频率等特性,以及综合前人的研究成果,采用陆上地震数据剩余静校正处理中的统计模型道互相关方法来实现对剖面反射同相轴的海浪改正处理;为减少强能量噪声对相关运算的影响,采用中值滤波、光滑滤波技术对反射同相轴曲线进行滤波处理,以进一步减少残留海浪的影响及相关运算改正误差。将这些方法综合运用于海上实际调查资料处理后,大风浪与涌浪影响下的波浪状反射同相轴变得连续、光滑,海底下混乱模糊的反射层位变得清晰、连续,剖面信噪比与分辨率得到了极大的提高。 相似文献
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因受海面大风浪与涌浪等影响,海上单道地震与浅地层剖面数据反射同相轴常出现波浪状起伏,造成剖面反射层位错乱,分辨率与信噪比降低。根据海浪噪声与海底反射地层在横向上的相关性与变化频率等特性,以及综合前人的研究成果,采用陆上地震数据剩余静校正处理中的统计模型道互相关方法来实现对剖面反射同相轴的海浪改正处理;为减少强能量噪声对相关运算的影响,采用中值滤波、光滑滤波技术对反射同相轴曲线进行滤波处理,以进一步减少残留海浪的影响及相关运算改正误差。将这些方法综合运用于海上实际调查资料处理后,大风浪与涌浪影响下的波浪状反射同相轴变得连续、光滑,海底下混乱模糊的反射层位变得清晰、连续,剖面信噪比与分辨率得到了极大的提高。 相似文献
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四分量海底地震仪(OBS)是一种新的接收仪器,其获得的地震数据信息量大,整体信噪比较高,频率成分丰富,具有较高的使用价值。OBS用于研究深部地壳结构已取得较好进展,但较少应用到油气勘探和盆地研究中。在南海西北部采用大容量气枪阵列(0.083m3)作为震源、利用OBS记录气枪震源的反射和折射信息,在油气勘探中是一种新的尝试。为正确使用OBS地震资料,必须采用不同于常规地震资料处理的方法,文中开拓性地使用了镜像叠前时间偏移处理方法。镜像叠前时间偏移处理方法是利用海面多次波进行成像的技术,包括OBS资料矢量保真处理、P分量(压力分量)和Z分量(垂直分量)的叠前处理和镜像叠前时间偏移处理等;其中矢量保真处理主要进行检波点位置二次重定位和检波点方向重定位及倾角校正,P、Z分量的叠前处理包括零相位化处理与地震道修改,P、Z矢量合并(P and Z summation)、剩余静校正、镜像叠加和多次波衰减等。采用镜像叠前时间偏移处理方法获得的剖面获得了较好的成像效果。 相似文献
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OBS广角反射地震及其意义 总被引:2,自引:0,他引:2
在蒸发岩、玄武岩等高阻抗岩层发育地区 ,常规反射地震往往难以获取高阻抗层以下的地层地质信息。而使用海底地震仪 ( OBS)进行广角反射地震测量 ,可较好地解决高阻抗层屏蔽问题 ,它是开展海上地质构造勘查的一种行之有效的方法。对 OBS广角反射地震法的原理 ,海上测量方法 ,资料处理 ,时间剖面解释及地下地质构造计算机模拟方法作了阐述 ,对 OBS广角反射地震勘探法的成功范例——苏伊士湾高蒸发岩发育区结晶基底勘探作一扼要介绍。 相似文献
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《海洋地质与第四纪地质》2014,(6)
以南黄海区域地质构造特征调查为目标,开展采集、处理技术方法攻关和海上试验等工作,形成了大容量多层震源、长缆深沉放多道地震采集技术和基于长排列、低信噪比的资料成像处理技术,提高了地震资料的成像品质,获得了深部地层的有效反射;得出了前新生代残留盆地分布面积大,中、古生代海相沉积地层发育,千里岩隆起区是扬子块体与华北块体碰触接触带等新认识,对南黄海区域地质与油气资源前景研究意义重大。 相似文献
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本文依据在南沙海域北康盆地及曾母盆地北部采集到的17000多公里地震剖面,对研究区地震反射特征进行了综合描述及地质属性初步分析。为寻找油气提供重要的基础指导。 相似文献
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Very high-frequency marine multichannel seismic reflection data generated by small-volume air- or waterguns allow detailed, high-resolution studies of sedimentary structures of the order of one to few metres wavelength. The high-frequency content, however, requires (1) a very exact knowledge of the source and receiver positions, and (2) the development of data processing methods which take this exact geometry into account. Static corrections are crucial for the quality of very high-frequency stacked data because static shifts caused by variations of the source and streamer depths are of the order of half to one dominant wavelength, so that they can lead to destructive interference during stacking of CDP sorted traces. As common surface-consistent residual static correction methods developed for land seismic data require fixed shot and receiver locations two simple and fast techniques have been developed for marine seismic data with moving sources and receivers to correct such static shifts. The first method – called CDP static correction method – is based on a simultaneous recording of Parasound sediment echosounder and multichannel seismic reflection data. It compares the depth information derived from the first arrivals of both data sets to calculate static correction time shifts for each seismic channel relative to the Parasound water depths. The second method – called average static correction method – utilises the fact that the streamer depth is mainly controlled by bird units, which keep the streamer in a predefined depth at certain increments but do not prevent the streamer from being slightly buoyant in-between. In case of calm weather conditions these streamer bendings mainly contribute to the overall static time shifts, whereas depth variations of the source are negligible. Hence, mean static correction time shifts are calculated for each channel by averaging the depth values determined at each geophone group position for several subsequent shots. Application of both methods to data of a high-resolution seismic survey of channel-levee systems on the Bengal Fan shows that the quality of the stacked section can be improved significantly compared to stacking results achieved without preceding static corrections. The optimised records show sedimentary features in great detail, that are not visible without static corrections. Limitations only result from the sea floor topography. The CDP static correction method generally provides more coherent reflections than the average static correction method but can only be applied in areas with rather flat sea floor, where no diffraction hyperbolae occur. In contrast, the average static correction method can also be used in regions with rough morphology, but the coherency of reflections is slightly reduced compared to the results of the CDP static correction method. 相似文献
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短排列多道反射地震接收缆较短,无水鸟、磁罗经、尾标等定位定深设备,给常规数据处理带来诸如观测系统定义等棘手问题;另外,无定深设备会造成接收缆不同接收段的沉放深度不同,破坏反射数据理论双曲线时距曲线关系。针对短排列多道反射地震数据,本文充分利用现场导航数据,计算实际激发点轨迹,再通过反距离比线性插值算法计算检波点的轨迹坐标,获得整个排列的实际观测系统参数。对因沉放深度不一致造成的扭曲时距曲线反射波,文中利用理论双曲线先计算共中心点道集的理论反射波位置,再推算排列中各接收道不同沉放深度处的静校正量,通过静校正拟合运算,消除接收排列非一致深度引起的反射波同相轴扭曲现象。将上述处理方法应用于南极海域短排列多道反射地震数据,最终获得了高分辨率叠加剖面,为后续地质解释提供了保障。 相似文献
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南海东沙海域的陆坡台地区, 浅表断裂及生物礁发育众多, 浅层新生界多为碳酸盐岩层, 中深层的中生界内部构造复杂, 断裂较多, 常规单船窄方位地震剖面显示中深层反射品质较差。利用双船可以设计灵活的观测系统, 形成双方位角地震探测方式, 对于地下同一反射点的照明, 可以获得比窄方位角探测更好的效果, 也可以改善高速屏蔽层下方、高陡倾角斜层等区域的成像质量。文章通过重点技术的攻关研发, 进行了单源激发、双缆接收的双方位角采集试验, 成功实现该方法在南海海域中深层地震勘探中的应用。 相似文献
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Hyeonju Kim Gwang Hoon Lee Bo Yeon Yi Youngho Yoon Kyong-O Kim Han-Joon Kim Sang Hoon Lee 《Ocean Science Journal》2017,52(2):283-292
In high-resolution, shallow-water seismic surveys, correction for water-column height variations caused by tides, weather, and currents is an important part of data processing. In this study, we present a very simple method of correction for profile-length (i.e., long-wavelength) water-column height variations for high-resolution seismic data using a reference bathymetric grid. First, the difference between the depth of the seafloor picked from seismic data and the bathymetry from the bathymetric grid is computed at the locations where the shot points of seismic profiles and the bathymetric grid points are collocated or closest. Then, the results are gridded and smoothed to obtain the profile-length water-column height variations for the survey area. Next, the water-column height variations for each seismic profile are extracted from the smoothed grid and converted to two-way traveltimes. The corrections for the remaining mis-ties at the intersections, computed within a circular region around each tie shot point, are added to the corrections for the water-column height variations. The final, mistie corrected water-column height corrections are loaded to the SEGY trace header of seismic data as a total static. We applied this method to the sparker data acquired from the shallow-water area off the western-central part of Korea where the tidal range is over 7 m. The corrections for water-column height variations range from -10 to 4 m with a median value of about -2 m. Large corrections occur locally between and near the islands probably due to the amplification and shortening in tidal wavelength caused by rapid shoaling toward the islands. 相似文献
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An on-board microwave radiometer can correct measurement errors due to rain attenuation for a satellite-borne microwave scatterometer, thereby allowing more accurate determination of the ocean-surface wind vector. In clear weather or when area-extensive homogeneous clouds and rain are present, corrections can be made properly even if the radiometer footprint is much larger than that of the scatterometer. When frontal or cyclonic storms are present, so that the rain and cloud distributions are nonuniform across the footprints, substantial errors remain in the "corrected" scatterometer measurements (in some cases "corrections" actually increase the errors). Simple-geometry simulations are reported here for nonidentical overlapping scatterometer and radiometer footprints with large gradients of attenuation and wind speed. In addition, examples are presented for a hurricane observed by the SEASAT-1 oceanographic satellite. These simulations demonstrate the size of the errors in wind speed (and direction for the hurricane) remaining after "correction." At higher wind speeds, the error is sometimes twice as large as the actual wind speed. The worst errors occur when the scatterometer footprint overlaps two or more radiometer footprints and the attenuation in the scatterometer footprint differs greatly from those in parts of the radiometer footprints. The presence of such large errors is inherent in systems having independent scan patterns for radiometer and scatterometer and having large radiometer footprints. A true radiometer-scatterometer system, having identical coincident footprints comparable in size with typical rain cells, could overcome this problem. 相似文献