TY - GEN
T1 - Straight ray datuming in 3D media - Fast and flexible
AU - Alkhalifah, T. A.
AU - Innemee, H.
AU - Benson, C.
PY - 2007
Y1 - 2007
N2 - Common datuming approaches, like the Kirchhoff or finite difference methods, are rarely applied to 3-D conventional land acquired data because they require reasonable sampling of the sources and receivers, which is not often the case with such data. To combat that, we extend Alkhalifah and Bagiani's (2006) straight ray datuming (SRD) to handle 3-D acquisition geometries. Like in the 2-D case, 3-D SRD is based on straight-rays assumption above and below the datum with Snell's law honored in between. This allows for the application of SRD to common shot gathers in one operation (no need to sort the data to common receivers). Similarly, it can be applied to common receiver gathers directly. This feature allows for more flexibility in acquisition as it requires, unlike in the conventional case, either the sources or receivers to have a complete fine coverage of the area. In addition, SRD does not require detail description of the near surface velocity model, information from refraction static or any other commonly used method to obtain near surface time shifts suffice. In addition, since the operation is a partial migration, it suppresses diffractions generated from inhomogeneities above datum.
AB - Common datuming approaches, like the Kirchhoff or finite difference methods, are rarely applied to 3-D conventional land acquired data because they require reasonable sampling of the sources and receivers, which is not often the case with such data. To combat that, we extend Alkhalifah and Bagiani's (2006) straight ray datuming (SRD) to handle 3-D acquisition geometries. Like in the 2-D case, 3-D SRD is based on straight-rays assumption above and below the datum with Snell's law honored in between. This allows for the application of SRD to common shot gathers in one operation (no need to sort the data to common receivers). Similarly, it can be applied to common receiver gathers directly. This feature allows for more flexibility in acquisition as it requires, unlike in the conventional case, either the sources or receivers to have a complete fine coverage of the area. In addition, SRD does not require detail description of the near surface velocity model, information from refraction static or any other commonly used method to obtain near surface time shifts suffice. In addition, since the operation is a partial migration, it suppresses diffractions generated from inhomogeneities above datum.
UR - http://www.scopus.com/inward/record.url?scp=55549133943&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:55549133943
SN - 9781605601557
T3 - 69th European Association of Geoscientists and Engineers Conference and Exhibition 2007: Securing The Future. Incorporating SPE EUROPEC 2007
SP - 1716
EP - 1720
BT - 69th European Association of Geoscientists and Engineers Conference and Exhibition 2007
PB - Society of Petroleum Engineers
T2 - 69th European Association of Geoscientists and Engineers Conference and Exhibition 2007 -
Y2 - 11 June 2007 through 14 June 2007
ER -