EEGS Short Course Processing of Seismic Refraction Tomography

EEGS Short Course Processing of Seismic Refraction Tomography

EEGS Short Course Processing of Seismic Refraction Tomography Data SAGEEP 2010 Keystone, Colorado April 10, 2010 Instructors Siegfried Rohdewald Intelligent Resources, Inc. [email protected] 604-782-9845

Jacob Sheehan Battelle Oak Ridge [email protected] 865-483-2538 Beth Burton USGS Denver [email protected] 303-236-1327 Schedule 13:00 13:10 13:10 13:40

Overview and introductions Introduction to refraction method & Rayfract 13:40 14:40 Rayfract tutorial dataset #1: Val de Travers 14:40 14:55 Break 14:55 15:45 15:45 17:00

Rayfract tutorial dataset #2: Success Dam Work on individual datasets Refraction Analysis Comparison ORIGINAL METHODS REFRACTION TOMOGRAPHY EXAMPLES Generalized reciprocal method (GRM) Delay-time method Slope-Intercept method Plus-minus method

Raytracing algorithms Numerical eikonal solvers Wavepath eikonal traveltime (WET) Generalized simulated annealing VELOCITY MODELS Layers defined by interfaces Not interface-based Can be dipping All layers have constant velocities

May define lateral velocity variations by dividing layer into finite blocks Limited number of layers Layers only increase in velocity with depth Typically requires more subjective input Assignment of traces to refractors Smoothly varying lateral & vertical vels. Can be difficult to image distinct, or abrupt, interfaces

Unlimited layers Imaging of discontinuous velocity inversions possible Typically requires less user input Smooth Inversion = 1D gradient initial model + 2D WET Wavepath Eikonal Traveltime tomography Get minimum-structure 1D gradient initial model : Top : pseudo-2D Delta-t-V display 1D Delta-t-V velocity-depth profile below each station 1D Newton search for each layer

velocity too low below anticlines velocity too high below synclines based on synthetic times for Broad Epikarst model (Sheehan, 2005a, Fig. 1). Bottom : 1D-gradient initial model generated from top by lateral averaging of velocities minimum-structure initial model Delta-t-V artefacts are completely removed 2D WET Wavepath Eikonal Traveltime inversion Fresnel volume or

wave path approach : rays that arrive within half period of fastest ray : tSP + tPR tSR <= 1 / 2f (Sheehan, 2005a, Fig. 2) nonlinear 2D optimization with steepest descent, to determine model update for one wavepath SIRT-like back-projection step, along wave paths instead of rays natural WET smoothing with wave paths (Schuster 1993, Watanabe 1999) partial modeling of finite frequency

wave propagation partial modeling of diffraction, around low-velocity areas WET parameters sometimes need to be adjusted, to avoid artefacts see RAYFRACT.HLP help file Supported Recording Geometries Compressional (P-) wave & shear (S-) wave interpretation Surface refraction, see appended tutorials Crosshole tomography, see IGTA13.PDF Multi-offset VSP, see WALKAWAY.PDF Zero-offset downhole VSP, see VSP.PDF Combine downhole shots with crosshole shots, if all receivers in

same borehole, for all shots POISSON.PDF: determine dynamic Poissons Ratio from P & S wave Supported Recording Geometries (cont.) Constrain surface refraction interpretation with uphole shots See COFFEY04.PDF. Use 1D-gradient initial model or constantvelocity Anisotropy: velocity may be dependent on predominant direction of ray and wave path propagation. This becomes visible directly adjacent to borehole. Imaged structure/layering is blurred out. Velocity inversions / low-velocity layers may become visible Walkaway VSP shots recorded with one or more boreholes may be converted to uphole shots by resorting traces by common receiver. Then import these exported uphole shots into one surface refraction

profile. Use two or more boreholes for improved resolution and reliability Survey Design Requirements and Suggestions Survey requirements 24 or more channels/receivers per shot recommended WET works with shots recorded only in one direction more reliable with shots recorded in both directions and reciprocal shots. This enables correction of picking errors. at least 1 shot every 3 receivers, ideally every 2 receivers

Survey design suggestions overlapping receiver spreads, so internal far offset shots can be used for WET tomography. receiver spreads should overlap by 30% to 50%. see OVERLAP.PDF and RAYFRACT.PDF chapter Overlapping receiver spreads, on your CD Station Numbering Concept Single station spacing defined for each profile Typically equivalent to receiver spacing

All receivers at integer station numbers Shot locations can be fractional station numbers Station spacing = greatest common divisor of all receiver spacings across profile Example: Rx position (ft/m) = 0, 5, 15, 25, 45, 50, 60,... Station spacing = 5 (ft/m) Rx position (station numbers) = 0, 1, 3, 5, 9, 10, 12,...

See Defining your own layout types in Rayfract Help|Contents Irregular Receiver Spread Types Supported Several standard receiver spread types already defined in Rayfract For input file formats SEG-2 and ASCII column format, you always need to define an irregular receiver spread type, even in case of missing channels e.g. at road crossing.

For all other input file formats e.g. Interpex Gremix, Geometrics SeisImager and OPTIM LLC SeisOpt , you dont need to define your own spread type if the spread layout used is regular, with constant channel separation (receiver spacing), and some channels missing e.g. due to road crossing. The default spread layout type 10: 360 channels will work fine in this case. The number of active channels used is recognized automatically by our import routine.

See Receiver spread types in Rayfract Help|Contents First Break Picks Reflections/ diffractions from cavity? ? Where to pick first breaks? ? ?

? Real dataset over cavity Raw data no filtering First Break Picks Art i HP fact o filte f ring ? Where to pick first breaks?

? Same real dataset over ? cavity rW Ai High-pass filter applied e av Caution: Wavelet precursor results

First Break Picks - Synthetic Cavity Data Easy First A rri v al Pi cking ! First Break Picks - Messy Real Cavity Data Messy Ar

ea f or picking Generalized Rayfract Flow Chart Create new profile database Define header information (minimum: Line ID, Job ID, instrument, station spacing (m)) Import data (ASCII first break picks or shot records) Update geometry information (shot & receiver positional information)

Run inversion Smooth invert|WET with 1D-gradient initial model (results output in Golden Softwares Surfer) Edit WET & 1Dgradient parameters & settings Smooth Inversion, DeltatV and WET Parameters always start with default parameters: run Smooth inversion without changing any setting or parameter next adapt parameters and option settings if required, e.g. to remove artefacts or increase resolution more smoothing and wider WET wavepath width in

general results in less artefacts increasing the WET iteration count generally improves resolution dont over-interpret data if uncertain picks : use more smoothing and/or wider wavepaths. explain traveltimes with minimum-structure model tuning of parameters and settings may introduce or remove artefacts. Be ready to go one step backwards. use Wavefront refraction method (Ali Ak, 1990) for independent velocity estimate. WET tomography main dialog: see help menu Number of WET tomography

iterations Default value is 20 iterations. Increase to 50 or 100 for better resolution and usually less artefacts. WET can improve with increasing iterations, even if RMS error does not decrease. Central Ricker Ricker wavelet used to modulate/weight the wavepath misfit wavelet frequency gradient, during model update. Leave at default of 50Hz. Degree of differentiation of Ricker wavelet 0 for original Ricker wavelet, 1 for once derived wavelet.

Default value is 0. Value 1 may give artefacts : wavepaths may become engraved in the tomogram. Wavepath width In percent of one period of Ricker wavelet. Increase width for smoother tomograms. Decreasing width too much generates artefacts and decreases robustness of WET inversion. Envelope wavepath width Width of wavepaths used to construct envelope at bottom of tomogram. Default is 0.0. Increase for deeper imaging.

Maximum valid velocity Limit the maximum WET velocity modeled. Default is 6,000 m/ s. Decrease to prevent high-velocity artefacts in tomogram. Full smoothing Default smoothing filter size, applied after each WET iteration Minimal smoothing

Select this for more details, but also more artefacts. May decrease robustness and reliability of WET inversion. WET tomography options in Settings submenu Scale wavepath width Scale WET filter height scale WET wavepath width with picked time, for each trace better weathering resolution, more smoothing at depth disable for wide shot spacing & short profiles (72 or less

receivers) to avoid artefacts also disable if noisy trace data and uncertain or bad picks scale height of smoothing filter with depth of grid row, below topography may decrease weathering velocity and pull up basement disable for short profiles, wide shot spacing and steep topography, and if uncertain picks Interpolate missing coverage after last iteration interpolate missing coverage at tomogram bottom, after last

iteration will always interpolate for earlier iterations use if receiver spreads dont overlap enough Disable wavepath scaling for short profiles automatically disable wavepath width scaling and scaling of smoothing filter height, for short profiles with 72 or less receivers this option is enabled per default, to avoid over-interpretation of small data sets, in case of bad picks

Smooth inversion options in Settings submenu to vary the 1D-gradient initial model set gradient-layer bottom velocity to Lower velocity (top velocity + bottom velocity) / 2 of 1D-gradient enable to lower the velocity of the overburden layers, and pull up layers the imaged basement disabled per default Interpolate velocity for 1D-gradient initial model

linearly interpolate averaged velocity vs. depth profile, to determine 1D-gradient initial model disable to model constant-velocity initial layers with the layer-top velocity assumed for the whole layer except the bottom-most 0.1m disable for sharper velocity increase at bottom of overburden. This may pull up basement as imaged with WET. enabled per default, since WET tomography works most reliably with smooth minimum-structure initial model, in both horizontal and vertical direction Delta-t-V Options in Settings submenu to vary the 1D-gradient initial model Enforce Monotonically disable to enhance low velocity anomaly imaging increasing layer

capability bottom velocity disabled per default Suppress velocity artefacts enforce continuous velocity vs. depth function use for medium to high coverage profiles only, to filter out bad picks and reflection events disabled per default, use for high-coverage profiles only Process every CMP offset

do Delta-t-V inversion at every offset recorded get better vertical resolution, possibly more artefacts disabled per default Smooth CMP traveltime curves use for high-coverage profiles only disable to get better vertical resolution disabled per default Max. velocity exported

Interactive Delta-t-V|Export Options setting set to 5,000 m/s per default decrease to e.g. 2,000 or 3,000 m/s and redo Smooth inversion, to vary WET output at bottom of tomogram Tutorial #1 Val de Travers, Switzerland, GeoExpert ag P-wave surface profile 29 shots, 48 traces per shot, roll-along recording with overlapping receiver spreads Receiver spacing = 5m Planning of a highway tunnel in an area prone to rockfalls, in Jura Mountains north of Geneva and near French border

Create new profile 1 Start up Rayfract software with desktop icon or Start menu 2 Select File|New Profile 3 Set File name to TRA9002 and click Save Fill in profile header 1 2 3 4 Select Header|Profile Use function key F1 for help on fields.

Set Line ID to TRA9002 and Job ID to Tutorial Set Instrument to Bison-2 9000 and Station spacing to 5m Hit ENTER, and confirm the prompt Seismic data import 1 Download and unzip http://rayfract.com/tutorials/TRA9002.ZIP to directory C:\RAY32\TUTORIAL 2 Select File|Import Data for Import shots dialog, see above 3 Set Import data type to Bison-2 9000 Series 4 Click Select button, select file TRAV0201 in directory C:\RAY32\TUTORIAL 5 Click on Open, Import shots, and confirm the prompt Import each shot

Click on Read for all shots shown in Import Shot dialog, see above. Dont change Layout start and Shot pos., these are correct already Update geometry and first breaks 1 2 3 4 Select File|Update header data|Update Station Coordinates Click on Select and C:\RAY32\TUTORIAL\TRA9002.COR Click on Open, Import File and confirm the prompt

Select File|Update header data|Update First Breaks and C:\RAY32\TUTORIAL\TRA9002.LST and click Open View and repick traces, display traveltime curves 1 2 3 4 5 6 7 8 9

Select Trace|Shot gather and Window|Tile. Browse shots with F7/F8 Click on Shot breaks window and press ALT-P Set Maximum time to 130 msecs. and hit ENTER Click on Shot traces window and press F1 twice to zoom time CTRL-F1 twice to zoom amplitude, CTRL-F3 twice to toggle trace fill mode Select Processing|Color traces and Processing|Color trace outline Use up/down/left/right arrow keys to navigate along and between traces Zoom spread with SHIFT-F1. Pan zoomed sections with SHIFT-PgDn/PgUp Optionally repick trace with left mouse key or space bar, delete first break with ALT-DEL or SHIFT-left mouse key. Press ALT-Y to redisplay traveltime curves Smooth inversion of first breaks : 1D-gradient initial model

1 Select Smooth invert|WET with 1D-gradient initial model 2 Once the 1D-gradient model is shown in Surfer, click on Rayfract icon at bottom of screen, to continue. Confirm following prompts. Smooth inversion of first breaks : 2D WET tomography 1 2 3 4 Click on Surfer icon shown at bottom of screen Select View|Object Manager to show outline at left, if not yet shown Click on Image in outline, right-select Properties.

Click on Colors spectrum, adjust Minimum and/or Maximum fields. Display modeled picks and traveltime curves 1 2 3 4 Click on Rayfract icon at bottom of screen Select Refractor|Shot breaks to view picked and modeled (blue) times Press F7/F8 keys to browse through shot-sorted traveltime curve Use Mapping|Gray picked traveltime curves to toggle curve pen style

Display WET wavepath coverage 1 Click on Surfer icon at bottom of screen 2 Use CTRL-TAB to cycle between WET tomogram, wavepath coverage plot and 1D-gradient initial model Optionally increase number of WET iterations 1 2 3 4 Click on Rayfract icon at bottom of screen

Select WET Tomo|Interactive WET tomography Change Number of WET tomography iterations to 100 Click button Start tomography processing, confirm prompts as above Tutorial #2 Success Dam, Porterville, CA, USGS P-wave surface profile 48 shots into 48 fixed geophones station spacing = 15ft Determine depth to bedrock, likelihood of liquefiable zones, define lateral continuity of geologic units, and identify faults/ fracture zones Create new profile

1 Start up Rayfract software with desktop icon or Start menu 2 Select File|New Profile 3 Set File name to LINE3P and click Save Fill in profile header 1 2 3 4 Select Header|Profile Use function key F1 for help on fields. Set Line ID to LINE3P and Job ID to Success Dam Tutorial

Set Instrument to unknown and Station spacing to 5m Hit ENTER, and confirm the prompt Seismic data import 1 2 3 4 5 6 Unzip http://rayfract.com/tutorials/LINE3P.ZIP to C:\RAY32\SUCCESS Select File|Import Data for Import shots dialog, see above

Set Import data type to SEG-2 Click Select button, set Files of type to ABEM files (*.SG2) Select file USGS01.SG2 in directory C:\RAY32\SUCCESS Click on Open, Import shots, and confirm the prompt Import each shot Click on Read for all shots shown in Import Shot dialog, see above. Dont change Layout start and Shot pos., these are correct already Update geometry and first breaks 1 2

3 4 5 6 Select File|Update header data|Update Station Coordinates Click on Select and C:\RAY32\SUCCESS\COORDS.COR Click on Open, Import File and confirm the prompt Select File|Update header data|Update Shotpoint coordinates Select C:\RAY32\SUCCESS\SHOTPTS.SHO, click Open, confirm prompt Select File|Update header data|Update First Breaks and C:\RAY32\SUCCESS\BREAKS.LST and click Open View and zoom traces, display traveltime curves

1 2 3 4 5 6 7 8 Select Trace|Shot gather and Window|Tile. Browse shots with F7/F8 Click on Shot breaks window and select Mapping|Gray picked traveltime curves Press ALT-P, set Maximum time to 90 msecs. and hit ENTER Click on Shot traces window and press F1 twice to zoom time

CTRL-F1 four times to zoom amplitude, CTRL-F3 twice to toggle trace fill mode Select Processing|Color traces and Processing|Color trace outline Use up/down/left/right arrow keys to navigate along and between traces Zoom spread with SHIFT-F1. Pan zoomed sections with SHIFT-PgDn/PgUp Smooth inversion of first breaks : 1D-gradient initial model 1 Select Smooth invert|WET with 1D-gradient initial model 2 Once the 1D-gradient model is shown in Surfer, click on Rayfract icon at bottom of screen, to continue. Confirm following prompts. Smooth inversion of first breaks : 2D WET tomography 1

2 3 4 Click on Surfer icon shown at bottom of screen Select View|Object Manager to show outline at left, if not yet shown Click on Image in outline, right-select Properties. Click on Colors spectrum, adjust Minimum and/or Maximum fields. Display WET wavepath coverage 1 Click on Surfer icon at bottom of screen 2 Use CTRL-TAB to cycle between WET tomogram, wavepath coverage plot and 1D-gradient initial model

Display modeled picks and traveltime curves 1 2 3 4 Click on Rayfract icon at bottom of screen Select Refractor|Shot breaks to view picked and modeled (blue) times Press F7/F8 keys to browse through shot-sorted traveltime curve Use Mapping|Gray picked traveltime curves to toggle curve pen style Increase WET iteration count to improve resolution

1 2 3 4 5 Select WET Tomo|Interactive WET tomography Click button Reset to reset WET parameters to default settings Change Number of WET tomography iterations to 100 Click button Start tomography processing, confirm prompts as above Note improved imaging of fault : velocity step in center of tomogram Flip over tomogram

1 2 3 4 5 Select Grid|Turn around grid file by 180 degrees Select file C:\RAY32\GRADTOMO\VELOIT100.GRD, click Open Select Grid|Image and contour velocity and coverage grids Select file C:\RAY32\GRADTOMO\VELOIT100.GRD, click Open Click on Surfer icon at bottom of screen, use CTRL-TAB to cycle Supplemental Success Dam Information

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