2,803
edits
Changes
Jump to navigation
Jump to search
Line 27:
Line 27: − +
→Tomographic data acquisition
With source and receivers in place, the source is fired and a recording is made. In traveltime tomography, this recording is later used to compute the time required for the seismic energy to travel from source to receiver. Data are acquired for every combination of source and receiver stations. Ray paths connecting sources and receivers for a typical survey are shown in [[:file:cross-borehole-tomography-in-development-geology_fig2.png|Figure 2]]. These traveltime data are then used to infer the seismic velocity field between the wellbores. If attenuation measurements can be made on the data, then the seismic Q-factor can also be imaged in the reservoir. Since the number of source/receiver pairs is usually in the thousands, data acquisition can be a slow process. Wirelines with multiple receivers appropriately placed can reduce the survey time.
With source and receivers in place, the source is fired and a recording is made. In traveltime tomography, this recording is later used to compute the time required for the seismic energy to travel from source to receiver. Data are acquired for every combination of source and receiver stations. Ray paths connecting sources and receivers for a typical survey are shown in [[:file:cross-borehole-tomography-in-development-geology_fig2.png|Figure 2]]. These traveltime data are then used to infer the seismic velocity field between the wellbores. If attenuation measurements can be made on the data, then the seismic Q-factor can also be imaged in the reservoir. Since the number of source/receiver pairs is usually in the thousands, data acquisition can be a slow process. Wirelines with multiple receivers appropriately placed can reduce the survey time.
Because usable seismic frequencies are an important factor in resolution, sources with the widest possible bandwidth are desirable, and data sampling rates of the recording instruments must be correspondingly high (usually on the order of 10,000 samples per second for each channel). Usually multicomponent receivers, which record data using three orthogonally mounted geophones, are used, so that both shear and compressional waves can be identified. If it is possible to reconstruct both compressional and shear wave tomograms, then ''V''<sub>p</sub>/''V''<sub>s</sub> and Poisson's ratio can be computed in the interwell volume.
Because usable seismic frequencies are an important factor in resolution, sources with the widest possible bandwidth are desirable, and data sampling rates of the recording instruments must be correspondingly high (usually on the order of 10,000 samples per second for each channel). Usually multicomponent receivers, which record data using three orthogonally mounted geophones, are used, so that both shear and compressional waves can be identified. If it is possible to reconstruct both compressional and shear wave tomograms, then ''V''<sub>p</sub>/''V''<sub>s</sub> and [http://en.wikipedia.org/wiki/Poisson%27s_ratio%20Poisson's%20ratio Poisson's ratio] can be computed in the interwell volume.
==Borehole source technology==
==Borehole source technology==