Difference between revisions of "UCERF3 Extended Earthquake Rupture Forecast"

From SCECpedia
Jump to navigationJump to search
(Created page with ' Phil and Scott, == Notes Creating UCERF3 EERF for CyberShake == I have finished verifying my MeanUCERF3 implementation, and have attached a table which shows comparisons with th…')
 
 
(2 intermediate revisions by the same user not shown)
Line 1: Line 1:
Phil and Scott,
 
 
== Notes Creating UCERF3 EERF for CyberShake ==
 
== Notes Creating UCERF3 EERF for CyberShake ==
I have finished verifying my MeanUCERF3 implementation, and have attached a table which shows comparisons with the full branch sweep aggregated over all 60 sites and 4 IMTs that are noted on this map:
+
KM has finished verifying a MeanUCERF3 implementation, and have attached a table which shows comparisons with the full branch sweep aggregated over all 60 sites and 4 IMTs that are noted on this map:
  
 
http://opensha.usc.edu/ftp/pmpowers/UCERF3.3/HazardCurves/Sites/
 
http://opensha.usc.edu/ftp/pmpowers/UCERF3.3/HazardCurves/Sites/
  
This allows you to weigh the trade-offs between fewer ruptures and more accuracy. At the maximum averaging level you'll have 373,661 ERF ruptures, as opposed to 4,905,378 without any averaging. Once I have gone over everything with Ned, we should open a dialog with Ned/Rob/Tom and possibly others about which parameter settings are best for CyberShake.
+
This allows us to weigh the trade-offs between fewer ruptures and more accuracy. At the maximum averaging level you'll have 373,661 ERF ruptures, as opposed to 4,905,378 without any averaging, and this should open a dialog about which parameter settings are best for CyberShake.
  
 
Here are descriptions for the MeanUCERF3 parameters:
 
Here are descriptions for the MeanUCERF3 parameters:
  
Sect Upper Depth Averaging Tolerance: Some fault sections have different aseismicity values across UCERF3 logic tree branches. These values change the upper depth of the fault section. If > 0, sections with upper depths within the given tolerance of the mean will be combined in order to reduce the overall section and rupture count.
+
*'''Sect Upper Depth Averaging Tolerance:''' Some fault sections have different aseismicity values across UCERF3 logic tree branches. These values change the upper depth of the fault section. If > 0, sections with upper depths within the given tolerance of the mean will be combined in order to reduce the overall section and rupture count.
  
Use Mean Upper Depth: If true and upper depth combine tolerance is > 0, mean upper depth will be used, else the shallowest upper depth will be used when averaging. Note that averaging does not incorporate participation rates, it is an unweighted mean and may not be representative.
+
*'''Use Mean Upper Depth:''' If true and upper depth combine tolerance is > 0, mean upper depth will be used, else the shallowest upper depth will be used when averaging. Note that averaging does not incorporate participation rates, it is an unweighted mean and may not be representative.
  
Rup Mag Averaging Tolerance: Each rupture has a suite of magnitudes from the different scaling relationships. These magnitudes can be averaged (within a tolerance) in order to reduce the total rupture count. Magnitudes are averaged weighted by their rate. Set to '1' to average all mags for each rupture.
+
*'''Rup Mag Averaging Tolerance:''' Each rupture has a suite of magnitudes from the different scaling relationships. These magnitudes can be averaged (within a tolerance) in order to reduce the total rupture count. Magnitudes are averaged weighted by their rate. Set to '1' to average all mags for each rupture.
  
Rupture Rake To Use: Each deformation model supplies rake values for each fault section (and thus each rupture). Invididual rakes can be used, or the rupture count can be reduced by either using the rate-averaged rake or rakes from a specific deformation model.
+
*'''Rupture Rake To Use:''' Each deformation model supplies rake values for each fault section (and thus each rupture). Invididual rakes can be used, or the rupture count can be reduced by either using the rate-averaged rake or rakes from a specific deformation model.
 +
 
 +
== Description ==
 +
*UCERF3 has more ruptures
 +
**UCERF2: 14,000
 +
**UCERF3: 200,000+
 +
*UCERF3 has Bigger/longer ruptures
 +
**Longest ruptures are low probability end-to-end San Andreas ruptures
 +
*UCERF3 has Multi fault ruptures
 +
** Between multiple “sections” of the same fault
 +
** Between different faults altogether

Latest revision as of 06:16, 10 November 2013

Notes Creating UCERF3 EERF for CyberShake

KM has finished verifying a MeanUCERF3 implementation, and have attached a table which shows comparisons with the full branch sweep aggregated over all 60 sites and 4 IMTs that are noted on this map:

http://opensha.usc.edu/ftp/pmpowers/UCERF3.3/HazardCurves/Sites/

This allows us to weigh the trade-offs between fewer ruptures and more accuracy. At the maximum averaging level you'll have 373,661 ERF ruptures, as opposed to 4,905,378 without any averaging, and this should open a dialog about which parameter settings are best for CyberShake.

Here are descriptions for the MeanUCERF3 parameters:

  • Sect Upper Depth Averaging Tolerance: Some fault sections have different aseismicity values across UCERF3 logic tree branches. These values change the upper depth of the fault section. If > 0, sections with upper depths within the given tolerance of the mean will be combined in order to reduce the overall section and rupture count.
  • Use Mean Upper Depth: If true and upper depth combine tolerance is > 0, mean upper depth will be used, else the shallowest upper depth will be used when averaging. Note that averaging does not incorporate participation rates, it is an unweighted mean and may not be representative.
  • Rup Mag Averaging Tolerance: Each rupture has a suite of magnitudes from the different scaling relationships. These magnitudes can be averaged (within a tolerance) in order to reduce the total rupture count. Magnitudes are averaged weighted by their rate. Set to '1' to average all mags for each rupture.
  • Rupture Rake To Use: Each deformation model supplies rake values for each fault section (and thus each rupture). Invididual rakes can be used, or the rupture count can be reduced by either using the rate-averaged rake or rakes from a specific deformation model.

Description

  • UCERF3 has more ruptures
    • UCERF2: 14,000
    • UCERF3: 200,000+
  • UCERF3 has Bigger/longer ruptures
    • Longest ruptures are low probability end-to-end San Andreas ruptures
  • UCERF3 has Multi fault ruptures
    • Between multiple “sections” of the same fault
    • Between different faults altogether