2 edition of Processing of Lake Baikal marine multichannel seismic reflection data found in the catalog.
Processing of Lake Baikal marine multichannel seismic reflection data
|Statement||by D.R. Hutchinson ... [et al.].|
|Series||Open-file report -- 92-243., U.S. Geological Survey open-file report -- 92-243.|
|Contributions||Hutchinson, Deborah R., Geological Survey (U.S.)|
|The Physical Object|
|Number of Pages||58|
Application-specific seismic data conditioning and processing for confident imaging From the field to the final volume, seismic data goes through many processes and workflows. Data conditioning encompasses a wide range of technologies designed to address numerous challenges in the processing sequence—from data calibration and regularization. This report consists of two-dimensional marine seismic reflection profile data from the northern Gulf of Mexico. These data were acquired in and with the Research Vessels Tommy Munro (MGM) and Gyre (GGM). The data are available in binary and GIF image formats. Binary data are in Society of Exploration Geologists (SEG) SEG-Y format and may be downloaded for further Cited by: 4.
A coincident marine MCS line was acquired using a m, ‐channel streamer with a group interval of m. The source was a in 3 II array. The shot interval was 50 m, resulting in a common‐mid‐point (CMP) fold of Processing and Data Analysis Refraction and Wide‐Angle Reflection Seismic DataCited by: the seismic data acquired at the surface, one can estimate the subsurface velocity distribution and map the corresponding structural features. For this purpose, each method implements its specific acquisition and processing techniques. A short general overview of shallow seismic File Size: 1MB.
Seismic Processing 25 Velocity model ExxonMobil Seismic Processing Field Record (marine) Data Processing Stream Subsurface ‘Image’ 26 Common Depth Point S are shots D are receivers Single-ended spread 12 channels 6-fold redundancy Sort the shot- receiver pairs that. Coastal and Marine Geology Program publications, listed by year: , Depositional and tectonic framework of the rift basins of Lake Baikal from multichannel seismic data: Geology (Boulder), v. K., Coleman, D. F., and Akentiev, L., , Processing of Lake Baikal marine multichannel seismic reflection data: U.S. Geological Survey Open.
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Processing of Lake Baikal marine multichannel seismic reflection data (SuDoc I ) [U.S. Geological Survey] on *FREE* shipping on qualifying : U.S. Geological Survey. approximately km of marine multichannel seismic reflection data in Lake Baikal, south-central Siberia, as part of a multidisciplinary, international program of research to study the geodynamics, paleolimnology, and paleoclimatology of the lake.
Lake Baikal is theCited by: 6. Get this from a library. Processing of Lake Baikal marine multichannel seismic reflection data. [Deborah R Hutchinson; Geological Survey (U.S.);]. Get this from a library.
Lake Baikal - processing of multichannel seismic reflection data. [W F Agena; Geological Survey (U.S.);]. This chapter represents a brief introduction to seismic data processing and provides a conventional processing flow for marine seismic data.
It explains the basic principles and definitions of the most common terms in underwater acoustics. Imaging of the deepest sedimentary section in Lake Baikal using multichannel seismic profiling was hampered by amplitude blanking that is regionally extensive, is associated with water depths.
Acquisition and Processing of Marine Seismic Data demonstrates the main principles, required equipment, and suitable selection of parameters in 2D/3D marine seismic data acquisition, as well as theoretical principles of 2D marine seismic data processing and their practical implications.
Featuring detailed datasets and examples, the book helps to relate theoretical background to real seismic data. Abstract. Imaging of the deepest sedimentary section in Lake Baikal using multichannel seismic profiling was hampered by amplitude blanking that is regionally extensive, is associated with water depths greater than about m and occurs at sub-bottom depths of 1–2 km in association with the first water-bottom by: 4.
1 Introduction to seismic data and processing Chapter contents Seismic data and their acquisition, processing, and interpretation Sampled time series, sampling rate, and aliasing Seismic amplitude and gain control Phase and Hilbert transforms Data format and quality control (QC) Summary Further readingFile Size: KB.
Thanks for these very helpful blogs, a welcome addition to the 2D Marine Processing tutorial. I'm currently working predominantly on shallow ultra high resolution seismic data (data.
Then we will discuss the main basic steps of a processing sequence, commonly used to obtain a seismic image and common to seismic data gathered on land (on-shore) as well as at sea (off-shore): CMP sorting, velocity analysis and NMO correction, stacking, (zero-offset) migration and time-to.
In the following the complete processing of seismic reflection data is described including import of the seismic data (chap.
I), crosscorrelation (optional for vibration data, ), setting the geometry (chap. III), filtering the shot data (chap. IV), performing the velocity analysis and stacking (chap.
Recent multichannel seismic reflection data from Lake Baikal, located in a large, active, continental rift in central Asia, image three major stratigraphic units totaling to km thick in four by: A sparker is a marine seismic impulsive source used for high-resolution seismic surveys.
Sparker sources were very popular during the late s and s before being supplanted by small volume airguns. However, in the last 10 years there has been renewed interest in sparker technology because (1) it can be easily deployed at relatively low costs and (2) in certain areas the Cited by: Ocean bottom seismometers operation during the seismic survey of Lake Baikal, Siberia, Autumn [micr Lake Baikal and its life / Mikhail Kozhov; Ozero Baikal = The Lake Baikal / [fotografii G.I.
Kuka i P. Petera ; tekst E. Vartaniana] Processing of Lake Baikal marine multichannel seismic reflection data [microform] / by D.R. Hutchinson. Hutchinson DR, Lee MW, Agena WF, Golmshtock AJ, Moskalenko VN, Karapetov K, Coleman DF, Akentiev L () Processing of Lake Baikal marine multichannel seismic reflection data.
USGS Open-File Rep – Google ScholarCited by: The bulk volume of gas hydrates in marine sediment can be estimated by measuring interval velocities and reflection amplitudes of hydrated zones from true-amplitude-processed multichannel seismic.
1. Free Download Acquisition and Processing of Marine Seismic Data PDF ; 2. Book details Author: Derman Dondurur Pages: pages Publisher: Elsevier Language: English ISBN ISBN Our seismic-reflection data were also used to choose the site for the ice-based drilling of two m core holes by the Baikal Drilling Project in March of Seen here in a satellite photo, Lake Baikal lies within an active continental rift, which is the target of ongoing studies of deep multichannel seismic-reflection studies (Hutchinson et al., ; Colman et al., ).
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All. Seismic reflection is the most widely used geophysical technique. It can be used to derive important details about the geometry of structures and their physical properties.
Major fields of application of Seismic reflection include: hydrocarbon exploration, research into . The late Cenozoic Baikal Rift Zone (BRZ) in southern Siberia is composed of several individual topographic depressions and half grabens with the deep Lake Baikal at its center.
We have modeled the seismic velocity structure of the crust and uppermost mantle along a km long profile of the Baikal Explosion Seismic Transects (BEST) project across the rift zone in the southern part of Lake.Reflection Seismic GEOL Method Principles Data acquisition Processing Data visualization Interpretation* Linkage with other geophysical methods* Reading: Gluyas and Swarbrick, Section Many books on reflection seismology (e.g., Telford et al.).