In this article we will see some general information about seismic data processing, this also give us some good basic knowledge about seismic it self. Here you are.
The method has three principal applications:
The method has three principal applications:
(a) Delineation of near-surface geology for engineering studies, and coal and mineral exploration within a depth of up to 1 km: The seismic method applied to the near-surface studies is known as engineering seismology.
(b) Hydrocarbon exploration and development within a depth of up to 10 km: The seismic method applied to the exploration and development of oil and gas fields is known as exploration seismology.
(c) Investigation of the earth's crustal structure within a depth of up to 100 km: The seismic method applied to the crustal and earthquake studies is known as earthquake seismology.
This book is devoted to application of the reflection seismic method to the exploration and development of oil and gas fields.
Conventional processing of reflection seismic data yields an earth image represented by a seismic section which usually is displayed in time. Figure 1-1 shows a seismic section from the Gulf of Mexico, nearly 40 km in length. Approximate depth scale indicates a sedimentary section of interbedded sands and shales down to 8 km. Note from this earth image a salt sill embedded in the sedimentary sequence. This allocthonous salt sill has a rugose top and a relatively smooth base. Note the folding and faulting of the sedimentary section above the salt.
The reflection seismic method has been used to delineate near-surface geology for the purpose of coal and mineral exploration and engineering studies, especially in recent years with increasing acceptance. Figure I-2a shows a seismic section along a 500-m traverse across a bedrock valley with steep flanks. The lithologic column based on borehole data indicates a sedimentary sequence of clay, sand, and gravel deposited within the valley. The bedrock is approximately 15 m below the surface at the fringes of the valley and 65 m below the surface at the bottom of the valley. The strong reflection at the sediment-bedrock boundary is a result of the contrast between the low-velocity sediments above and the high-velocity Precambrian quartz pegmatite below.
FIG. 1-2. (a) A shallow reflection seismic section from Ontario (Pullan and Hunter, 1990), and (b) a deep reflection seismic section from southeast Turkey (Yilmaz, 1976).
The reflection seismic method also has been used to delineate the crustal structure down to the Moho discontinuity and below. Figure I-2b shows a seismic section recorded on land along a 15-km traverse. Based on regional control, it is known that the section consists of sediments down to about 4 km. The reflection event at 6.5-7 s, which corresponds to a depth range of 15-20 km, can be postulated as the crystalline basement. The group of reflections between 8-10 s, which corresponds to a depth range of 25-35 km, represents a transition zone in the lower crust most likely, the Moho discontinuity, itself.
Common-midpoint (CMP) recording is the most widely used seismic data acquisition technique. By providing redundancy, measured as the fold of coverage in the seismic experiment, it improves signal quality. Figure 1-3 shows seismic data collected along the same traverse in 1965 with single-fold coverage and in 1995 with twelve-fold coverage. These two different vintages of data have been subjected to different treatments in processing; nevertheless, the fold of coverage has caused the most difference in the signal level of the final sections.
FIG. 1-3. (a) A single-fold section obtained in 1965, and (b) a twelve-fold section obtained in 1995 along the same line
traverse. (Data courtesy Turkish Petroleum Corp.)
FIG. 1-4. The poor signal between midpoints A and B on this seismic section is caused by a karstic limestone on the surface.
FIG. 1-5. The lack of coherent reflections to the right of midpoint A on this seismic section results from the surface charges used during recording. By using charges placed in holes below the karstic limestone in the near surface, signal penetration has been improved to the left of midpoint A.)
Besides surface conditions, environmental and demographic restrictions can have a significant impact on field data quality. The part of the seismic section shown in Figure 1-6 between midpoints A and B is through a village. In the village, the vibroseis source was not operated with full power. Hence, not enough energy penetrated into the earth. Although surface conditions were similar along the entire line, the risk of property damage resulted in poor signal quality in the middle portion of the line.
Other factors, such as weather conditions, care taken during recording, and the condition of the recording equipment, also influence data quality. Almost always, seismic data are collected often in less-than-ideal conditions. Hence, we can only hope to attenuate the noise and enhance the signal in processing to the extent allowed by the quality of the data acquisition.
In addition to field acquisition parameters, seismic data processing results also depend on the techniques used in processing. A conventional processing sequence almost always includes the three principal processes deconvolution, CMP stacking, and migration.
This is the end of Oz Yilmaz Introduction on his book seismic data processing volume I, it give us some general information about the book and seismic method.
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