Gallery of Images -- Lamont 4D Software Manual
Chapter 1
Figure 1.1: AVS network of data loader and interface
Figure 1.2 Result of an example data loading and parameter setup
Figure 1.3: Result of data manipulation and its network
Chapter 2
Figure 2.1: AVS network for 3D seismic reorientation
Figure 2.2: Seismic interpolation method for orientation
Figure 2.3 Before and after rebinning
Chapter 3
Figure 3.1: Network for seismic viewing
Figure 3.2: Seis view module controller and basemap display window
Figure 3.3: Seis view module controller and display window for data
Figure 3.4: AVS network to visualize seismic data in orthogonal slices
Figure 3.5: AVS network to visualize seismic data in volumetric surfaces
Figure 3.5.1: Region grown volume in 3D
Figure 3.6: AVS network to visualize horizon mapping
Chapter 4
Figure 4.1: AVS network to do cross correlation
Figure 4.1.1: Wiggle Plot of before and after cross correlation
Chapter 5
Figure 5.1: An exemplary network of the module "horizon dump"
Figure 5.2: Control interface of the module "horizon dump"
Chapter 6
Figure 6.1: An exemplary network to compute seismic attributes.
Chapter 7
Figure 7.1: An exemplary network to accomplish amplitude and frequency normalization
Figure 7.2: control panel for the amplitude matcher module
Figure 7.3: Frequency spectrums and histograms before normalization
Figure 7.4: Frequency spectrums and histograms after normalization
Figure 7.5: Seismic images before and after normalization
Chapter 8
Figure 8.1: An exemplary network to do median filtering.
Chapter 9
Figure 9.1: An exemplary network to do region growing
Chapter 11
Figure 11.1: An exemplary network to do differencing and similarity analysis
Figure 11.2.1: An exemplary network to map seismic and difference to the horizon
Figure 11.2.2: The resultant image from the network of the Figure 11.2.1
Figure 11.2.3: Another exemplary network to visualize the region union differences
Figure 11.2.4: One frame generated by the network in Figure 11.2.3
Figure 11.2.5: Another exemplary network to visualize the region union difference in animation
Figure 11.2.6: One frame generated by the network in Figure 11.2.5
Chapter 12
Figure 12.1.1 is an example network to visualize well data with seismic data, etc.
Figure 12.1.2 is the rendered well bore. In this example, three wells are rendered as cylinders in black.
Figure 12.1.3 is the image which maps data onto the surface of the well bore.
Figure 12.1.4 is the log curve which is rendered as a polyline stripe with certain width.
Figure 12.1.5 is the extracted data along the well path which is drawn as polyline stripe.
Figure 12.1.6 is the slice extracted along the well path.
Chapter 13
Figure 13.1 Horizon tracker interface and result.
Figure 13.2 Horizon identifier interface
Figure 13.3 Geostructure visualizer and result.
Chapter 15
Figure 15-1. An example network to perform seismic inversion using
Invert_3D_ED
.
Figure 15-2. An example of using interactive X-Y plotting utility to check the inversion of a seismic trace from
Invert_3D_ED
Figure 15-3. The time 1 seismic survey.
Figure 15-4. The time 2 seismic survey.
Figure 15-5(a). The wavelet volume estimated from the time 1 seismic volume in the inversion process.
Figure 15-5(b). The wavelet volume estimated from the time 1 seismic volume in the inversion process.
Figure 15-6(a). The wavelet volume estimated from the time 2 seismic volume in the inversion process.
Figure 15-6(b). The wavelet volume estimated from the time 2 seismic volume in the inversion process.
Figure 15-7. The inverted acoustic impedance volume from time 1 seismic survey.
Figure 15-8. The inverted acoustic impedance volume from time 2 seismic survey.
Figure 15-9. An example network to perform parametric seismic inversion using
Invert_3D_OD
Figure 15-10. An example plot of partial inversion results using module
Invert_3D_OD
.
