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Journal Article

M‐Split: A Graphical User Interface to Analyze Multilayered Anisotropy from Shear‐Wave Splitting Available to Purchase

Bizhan Abgarmi, A. Arda Özacar
Published: 17 May 2017
Seismological Research Letters (2017) 88 (4): 1146–1155.
DOI: https://doi.org/10.1785/0220170020
... to model them. Most commonly, such complexities are modeled using multiple anisotropic layers with priori constraints from geologic data. In this study, a graphical user interface called M‐Split is developed to easily process and model multilayered anisotropy with capabilities to properly address...
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View PDF for article title, M‐Split: A <span class="search-highlight">Graphical</span> <span class="search-highlight">User</span> <span class="search-highlight">Interface</span> to Analyze Multilayered Anisotropy from Shear‐Wave Splitting
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Default Crazyseismic Pick graphic user interface (GUI). It comprises eight different panels. The central part is used for displaying waveforms. (Refer to the software manual for more details of parameters and functions.)The color version of this figure is available only in the electronic edition.

Default Crazyseismic Pick graphic user interface (GUI). It comprises eight ... Available to Purchase

Published: 25 January 2017
Figure 1. Default Crazyseismic Pick graphic user interface (GUI). It comprises eight different panels. The central part is used for displaying waveforms. (Refer to the software manual for more details of parameters and functions.)The color version of this figure is available only
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Graphic user interface of REXEL-DISP and main required information or record selection options.

Graphic user interface of REXEL-DISP and main required information or recor... Available to Purchase

Published: 01 November 2014
Figure 9. Graphic user interface of REXEL-DISP and main required information or record selection options.
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Graphical user interface of the RCH software showing the Raman spectrum of a kyanite inclusion in a lithospheric diamond (Nestola et al. 2018). The window indicated as box 1 is the main window where resultant spectra are displayed after processing. The window indicated as box 2 is the preview window allowing the user to preview the results of all operations before they are finalized.

Graphical user interface of the RCH software showing the Raman spectrum of ... Open Access

Published: 01 April 2025
Figure 1. Graphical user interface of the RCH software showing the Raman spectrum of a kyanite inclusion in a lithospheric diamond ( Nestola et al. 2018 ). The window indicated as box 1 is the main window where resultant spectra are displayed after processing. The window indicated as box 2
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Graphical user interface of PBRslenderness. The user loads the precariously balanced rock (PBR) photograph and interactively digitizes its rocking points and outline. PBRslenderness then computes the PBR two-dimensional (2D) geometric parameters α1, α2, R1, and R2.

Graphical user interface of PBRslenderness. The user loads the precariously... Open Access

Published: 01 October 2012
Figure 3. Graphical user interface of PBRslenderness. The user loads the precariously balanced rock (PBR) photograph and interactively digitizes its rocking points and outline. PBRslenderness then computes the PBR two-dimensional (2D) geometric parameters α 1 , α 2 , R 1 , and R 2 .
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The graphical user interface of the Log Digitizer. ID = identification.

The graphical user interface of the Log Digitizer. ID = identification. Available to Purchase

Published: 01 March 2024
Figure 8. The graphical user interface of the Log Digitizer. ID = identification.
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Example data windows within the graphical user interface (GUI) for CI.GR2 station. The color version of this figure is available only in the electronic edition.

Example data windows within the graphical user interface (GUI) for CI.GR2 s... Available to Purchase

Published: 29 December 2021
Figure 8. Example data windows within the graphical user interface (GUI) for CI.GR2 station. The color version of this figure is available only in the electronic edition.
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The digital filter graphical user interface (GUI), which includes a low‐pass filter (LPFilter) and a band‐pass filter (BPFilter). For the filter parameters, Fs is the sample rate of the original seismic recording, which can usually be read from the seismic data file or can be set by the user. In the LPFilter part, LPfp is the edge frequency of the passband; LPfs is the edge frequency of the stopband; and the corresponding cutoff frequency of the LPFilter can be defined as Fc=(LPfp+LPfs)/2. In the BPFilter part, Fs1 is the lower edge frequency of the stopband; Fp1 is the lower edge frequency of the passband; Fs2 is the upper edge frequency of the stopband; Fp2 is the upper edge frequency of the passband; and the corresponding cutoff frequency of the BPFilter can be defined as Fc=[Fs1+Fp1)/2,Fs2+Fp2)/2].

The digital filter graphical user interface (GUI), which includes a low‐pas... Available to Purchase

Published: 07 July 2021
Figure 3. The digital filter graphical user interface (GUI), which includes a low‐pass filter (LPFilter) and a band‐pass filter (BPFilter). For the filter parameters, Fs is the sample rate of the original seismic recording, which can usually be read from the seismic data file or can be set
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System graphical user interface (GUI).

System graphical user interface (GUI). Available to Purchase

Published: 01 August 2020
Figure 11. System graphical user interface (GUI).
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Example of SeisanExplorer screen. The database Graphical User Interface (GUI) is shown at the top left with the list of events. From here, the plotting program (top right) and locator (bottom right) are started. For mapping, GoogleEarth (bottom left) is used in which the view is updated automatically to show the epicenter and stations. Stations are color coded based on their residual.

Example of SeisanExplorer screen. The database Graphical User Interface (GU... Available to Purchase

Published: 18 March 2020
Figure 3. Example of SeisanExplorer screen. The database Graphical User Interface (GUI) is shown at the top left with the list of events. From here, the plotting program (top right) and locator (bottom right) are started. For mapping, GoogleEarth (bottom left) is used in which the view is updated
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Layout of the MATLAB graphical user interface for RSFit3000, with labeled features. Detailed information on use of the graphical user interface can be found in the user guide (Supplemental File 1 [text footnote 1]). (A) Experiment Data panel. (B) Windowing axes. (C) Static axes. (D) Detrending Parameters panel. (E) Fitting axes. (F) Event Type panel. (G) Fitting Options panel. (H) Weight Parameters panel. (I) Velocity Step Parameters panel. (J) Slide-Hold-Slide Parameters panel. (K) Normal Stress display. (L) Fitting Parameters panel. (M) Create Structure button.

Layout of the MATLAB graphical user interface for RSFit3000, with labeled f... Open Access

Published: 10 September 2019
Figure 3. Layout of the MATLAB graphical user interface for RSFit3000, with labeled features. Detailed information on use of the graphical user interface can be found in the user guide (Supplemental File 1 [text footnote 1 ]). (A) Experiment Data panel. (B) Windowing axes. (C) Static axes
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The graphical user interface of 3DMRT. The main window is a 3D environment that is used to visualize 3D objects, velocity models, travel times, and ray trajectories. The main functionalities can be accessed via the menu bar. A synthetic velocity model with the fastest ray path from the start to the goal point, as well as its travel time, is shown.

The graphical user interface of 3DMRT. The main window is a 3D environment ... Available to Purchase

Published: 07 August 2019
Figure 1. The graphical user interface of 3DMRT. The main window is a 3D environment that is used to visualize 3D objects, velocity models, travel times, and ray trajectories. The main functionalities can be accessed via the menu bar. A synthetic velocity model with the fastest ray path from
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The main graphical user interface (GUI, command s2s show …). Note that because of JavaScript libraries, plots are not static images but interactive objects. The data to be visualized therein and their placement are customizable via a custom processing module and a processing config. The color version of this figure is available only in the electronic edition.

The main graphical user interface (GUI, command s2s show …). Note that be... Available to Purchase

Published: 26 June 2019
Figure 2. The main graphical user interface (GUI, command s2s show …). Note that because of JavaScript libraries, plots are not static images but interactive objects. The data to be visualized therein and their placement are customizable via a custom processing module and a processing config
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LIME graphical user interface, showing a three-dimensional (3-D) unmanned aerial vehicle–based photogrammetric model (Bolea, Ebro Basin, Spain; data from https://safaridb.com) and interpreted lines and planes. Two gridded horizons (transparent yellow, red wireframe) are shown. The interface is made up of the data element tree (left) and 3-D scene (right), and additional dialogs are used for tasks such as editing the display settings of objects and placing or creating data.

LIME graphical user interface, showing a three-dimensional (3-D) unmanned a... Open Access

Published: 10 January 2019
Figure 1. LIME graphical user interface, showing a three-dimensional (3-D) unmanned aerial vehicle–based photogrammetric model (Bolea, Ebro Basin, Spain; data from https://safaridb.com ) and interpreted lines and planes. Two gridded horizons (transparent yellow, red wireframe) are shown
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A snapshot of “CrazyTremor,” a MATLAB graphical user interface (GUI)–based package consisting of five main control panels: (i) map, (ii) tremor‐band seismograms, (iii) surface‐waveband seismograms, (iv) switching between events and lists, and (v) input and output. The screen demonstrates triggered tremor in the central region of the Alpine fault in the South Island of New Zealand (panel i) after the 2005 Mw 8.6 Nias earthquake. Triggered tremor signals are shown on the 2‐ to 8‐Hz bandpass‐filtered seismograms (panel ii) during the arrival of Rayleigh waves (panel iii). The color version of this figure is available only in the electronic edition.

A snapshot of “CrazyTremor,” a MATLAB graphical user interface (GUI)–based ... Available to Purchase

Published: 05 September 2018
Figure 1. A snapshot of “CrazyTremor,” a MATLAB graphical user interface (GUI)–based package consisting of five main control panels: (i) map, (ii) tremor‐band seismograms, (iii) surface‐waveband seismograms, (iv) switching between events and lists, and (v) input and output. The screen
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Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu); (2) available load geometry (pulldown menu); (3) changing the flexural rigidity (slider); and (4) changing the load magnitude (slider). Clicking on the red circle resets the figure to its initial display. Other model parameters controlled with sliders and text boxes are the load position, load wavelength for harmonic loads, and plate density structure (infill density, crust density, mantle density, and the respective interface depths). Plot appearance is controlled with “Xmin”, “Xmax”, and “Spacing” in the “Plot Parameters” panel. Flexure or gravity data can be imported using the “Data Import Utility”, which prompts for an input file name. The data are plotted by clicking the “Plot Data” button. X, Y, and Z buttons and edit box in the “Data Shift” panel allow data to be shifted horizontally and vertically to adjust the model fit. Buttons to interact with the imported data and plots are also provided. The flexural parameter (α [indicated as Alpha in the TAFI GUI]), zero crossing distance (x0 [X0 in the GUI]), flexural bulge position (xb [Xb in the GUI]), the maximum flexural depth (wmax [Wmax in the GUI]) and the amplitude of peripheral bulge (wb [Wb in the GUI]) are displayed in the “Outputs” panel. Flexure and gravity models and imported data are shown in the plot panel.

Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (... Open Access

Published: 11 September 2017
Figure 3. Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu
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Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu); (2) available load geometry (pulldown menu); (3) changing the flexural rigidity (slider); and (4) changing the load magnitude (slider). Clicking on the red circle resets the figure to its initial display. Other model parameters controlled with sliders and text boxes are the load position, load wavelength for harmonic loads, and plate density structure (infill density, crust density, mantle density, and the respective interface depths). Plot appearance is controlled with “Xmin”, “Xmax”, and “Spacing” in the “Plot Parameters” panel. Flexure or gravity data can be imported using the “Data Import Utility”, which prompts for an input file name. The data are plotted by clicking the “Plot Data” button. X, Y, and Z buttons and edit box in the “Data Shift” panel allow data to be shifted horizontally and vertically to adjust the model fit. Buttons to interact with the imported data and plots are also provided. The flexural parameter (α [indicated as Alpha in the TAFI GUI]), zero crossing distance (x0 [X0 in the GUI]), flexural bulge position (xb [Xb in the GUI]), the maximum flexural depth (wmax [Wmax in the GUI]) and the amplitude of peripheral bulge (wb [Wb in the GUI]) are displayed in the “Outputs” panel. Flexure and gravity models and imported data are shown in the plot panel.

Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (... Open Access

Published: 11 September 2017
Figure 3. Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu
Image
Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu); (2) available load geometry (pulldown menu); (3) changing the flexural rigidity (slider); and (4) changing the load magnitude (slider). Clicking on the red circle resets the figure to its initial display. Other model parameters controlled with sliders and text boxes are the load position, load wavelength for harmonic loads, and plate density structure (infill density, crust density, mantle density, and the respective interface depths). Plot appearance is controlled with “Xmin”, “Xmax”, and “Spacing” in the “Plot Parameters” panel. Flexure or gravity data can be imported using the “Data Import Utility”, which prompts for an input file name. The data are plotted by clicking the “Plot Data” button. X, Y, and Z buttons and edit box in the “Data Shift” panel allow data to be shifted horizontally and vertically to adjust the model fit. Buttons to interact with the imported data and plots are also provided. The flexural parameter (α [indicated as Alpha in the TAFI GUI]), zero crossing distance (x0 [X0 in the GUI]), flexural bulge position (xb [Xb in the GUI]), the maximum flexural depth (wmax [Wmax in the GUI]) and the amplitude of peripheral bulge (wb [Wb in the GUI]) are displayed in the “Outputs” panel. Flexure and gravity models and imported data are shown in the plot panel.

Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (... Open Access

Published: 11 September 2017
Figure 3. Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu
Image
Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu); (2) available load geometry (pulldown menu); (3) changing the flexural rigidity (slider); and (4) changing the load magnitude (slider). Clicking on the red circle resets the figure to its initial display. Other model parameters controlled with sliders and text boxes are the load position, load wavelength for harmonic loads, and plate density structure (infill density, crust density, mantle density, and the respective interface depths). Plot appearance is controlled with “Xmin”, “Xmax”, and “Spacing” in the “Plot Parameters” panel. Flexure or gravity data can be imported using the “Data Import Utility”, which prompts for an input file name. The data are plotted by clicking the “Plot Data” button. X, Y, and Z buttons and edit box in the “Data Shift” panel allow data to be shifted horizontally and vertically to adjust the model fit. Buttons to interact with the imported data and plots are also provided. The flexural parameter (α [indicated as Alpha in the TAFI GUI]), zero crossing distance (x0 [X0 in the GUI]), flexural bulge position (xb [Xb in the GUI]), the maximum flexural depth (wmax [Wmax in the GUI]) and the amplitude of peripheral bulge (wb [Wb in the GUI]) are displayed in the “Outputs” panel. Flexure and gravity models and imported data are shown in the plot panel.

Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (... Open Access

Published: 11 September 2017
Figure 3. Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu
Image
Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu); (2) available load geometry (pulldown menu); (3) changing the flexural rigidity (slider); and (4) changing the load magnitude (slider). Clicking on the red circle resets the figure to its initial display. Other model parameters controlled with sliders and text boxes are the load position, load wavelength for harmonic loads, and plate density structure (infill density, crust density, mantle density, and the respective interface depths). Plot appearance is controlled with “Xmin”, “Xmax”, and “Spacing” in the “Plot Parameters” panel. Flexure or gravity data can be imported using the “Data Import Utility”, which prompts for an input file name. The data are plotted by clicking the “Plot Data” button. X, Y, and Z buttons and edit box in the “Data Shift” panel allow data to be shifted horizontally and vertically to adjust the model fit. Buttons to interact with the imported data and plots are also provided. The flexural parameter (α [indicated as Alpha in the TAFI GUI]), zero crossing distance (x0 [X0 in the GUI]), flexural bulge position (xb [Xb in the GUI]), the maximum flexural depth (wmax [Wmax in the GUI]) and the amplitude of peripheral bulge (wb [Wb in the GUI]) are displayed in the “Outputs” panel. Flexure and gravity models and imported data are shown in the plot panel.

Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (... Open Access

Published: 11 September 2017
Figure 3. Toolbox for Analysis of Flexural Isostasy (TAFI) graphical user interface (GUI). When viewed in the PDF of this paper using Adobe Acrobat or Reader, clicking on green circles activates a dynamic figure demonstrating GUI features. These include (1) available plate geometry (pulldown menu