Difference between revisions of "CyberShake Study 18.8"

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For our second test, we selected an individual point in the above CyberShake event and simulated a point source about 20 km SW of the model interface, with the same simulation parameters (minimum Vs of 500 m/s, dt=0.005, nt=20000, so 100 sec of simulation time).  A visualization is available [http://hypocenter.usc.edu/research/cybershake/study_18_5/fwd_sims/point_src.mp4 here]; the USGS Bay Area region is in green, and the CCA-06 region is in red.  Note that the USGS region has a GTL but the CCA region does not.
 
For our second test, we selected an individual point in the above CyberShake event and simulated a point source about 20 km SW of the model interface, with the same simulation parameters (minimum Vs of 500 m/s, dt=0.005, nt=20000, so 100 sec of simulation time).  A visualization is available [http://hypocenter.usc.edu/research/cybershake/study_18_5/fwd_sims/point_src.mp4 here]; the USGS Bay Area region is in green, and the CCA-06 region is in red.  Note that the USGS region has a GTL but the CCA region does not.
  
We added the Ely GTL to the CCA model for this region (surface plot below) and reran the point-source simulation (with additional filtering).  A visualization is available [http://hypocenter.usc.edu/research/cybershake/study_18_5/fwd_sims/point_src_gtl.mp4 here].
+
We added the Ely GTL to the CCA-06 model for this region and reran the point-source simulation (with additional filtering).  A visualization is available [http://hypocenter.usc.edu/research/cybershake/study_18_5/fwd_sims/point_src_gtl.mp4 here].
  
[[File:gtl_surface_plot.png|thumb|px400]]
+
Below are plots comparing the surface without and with the Ely GTL on CCA-06.
 +
 
 +
{|
 +
| [[File:nogtl_surface_plot.png|thumb|px400|No GTL, surface plot]]
 +
| [[File:gtl_surface_plot.png|thumb|px400|GTL, surface plot]]
 +
|}
  
 
=== Alternative Velocity Model Plots ===
 
=== Alternative Velocity Model Plots ===

Revision as of 15:00, 7 May 2018

CyberShake 18.3 is a computational study to perform CyberShake in a new region, the extended Bay Area. We plan to use a combination of 3D models (USGS Bay Area detailed and regional, CVM-S4.26.M01, CCA-06) with a minimum Vs of 500 m/s and a frequency of 1 Hz. We will use the GPU implementation of AWP-ODC-SGT, the Graves & Pitarka (2014) rupture variations with 200m spacing and uniform hypocenters, and the UCERF2 ERF. The SGT and post-processing calculations will both be run on both NCSA Blue Waters and OLCF Titan.

Status

This study is under development. We hope to begin in March 2018.

Science Goals

The science goals for this study are:

  • Expand CyberShake to the Bay Area.
  • Calculate CyberShake results with the USGS Bay Area velocity model as the primary model.

Technical Goals

  • Perform the largest CyberShake study to date.

Sites

Map showing Study 18.3 sites (cities=yellow, CISN stations=orange, missions=blue, 10 km grid=purple, 5 km grid=green, PG&E locations=pink. The Bay Area box is in orange and the Study 17.3 box is in magenta.

The Study 18.3 box is 180 x 390 km, with the long edge rotated 27 degrees counter-clockwise from vertical. The corners are defined to be:

South: (-121.51,35.52)
West: (-123.48,38.66)
North: (-121.62,39.39)
East: (-119.71,36.22)

We are planning to run 869 sites, 838 of which are new, as part of this study.

These sites include:

  • 77 cities (74 new)
  • 10 new missions
  • 139 CISN stations (136 new)
  • 46 new sites of interest to PG&E
  • 597 sites along a 10 km grid (571 new)

Of these sites, 32 overlap with the Study 17.3 region for verification.

A KML file with all these sites is available with names or without names.

Projection Analysis

As our simulation region gets larger, we needed to review the impact of the projection we are using for the simulations. An analysis of the impact of various projections by R. Graves is summarized in this posting:

Velocity Models

For Study 18.3, the first velocity model, we examined was the following order of precedence:

  1. USGS Bay Area model
  2. CCA-06
  3. CVM-S4.26.M01 which include a 1D background model

We will apply a minimum Vs of 500 m/s. We will smooth to a distance of 10 km either side of a velocity model interface. A KML file showing the model regions is available here.

We had originally planned to query them in the order 1) USGS Bay Area; 2) CVM-S4.26.M01; 3) CCA-06; 4) 1D background; but upon inspection of the cross-sections, CCA-06 seems to capture the Great Valley basins better than CVM-S4.26, leading to better agreement with the southern edge of the USGS Bay Area model. We are investigating adding the Ely GTL to the CCA-06 model to compensate for the lack of low-velocity, near-surface structure in CCA-06, since the tomographic inversion was performed at 900 m/s.

An alternative velocity model, under consideration for this simulation is based on tiling the models in the following order:

  1. USGS Bay Area model
  2. CCA-06 with Ely GTL
  3. CVM-S4.26 with Ely GTL
  4. BBP 1D model

Forward simulations

To check the smoothing region, we performed forward simulations near the USGS/CCA-06 boundary, in a volume 270 x 300 x 50 km. The corners of the region are:

-120.5,34,0
-121.93426,36.12917
-118.98101,37.41772
-117.60821,35.25771

For our first test, we selected the CyberShake event ERF ID 36, source ID 60, rupture ID 3, rupture variation 13, a south-to-north M6.95 on the Cholame segment of the San Andreas. We ran with a minimum Vs of 500 m/s, dt=0.005, nt=20000, so 100 sec of simulation time. A visualization of the results is available here; the USGS Bay Area region is in green, and the CCA-06 region is in red. Note that the USGS region has a GTL but the CCA region does not.

For our second test, we selected an individual point in the above CyberShake event and simulated a point source about 20 km SW of the model interface, with the same simulation parameters (minimum Vs of 500 m/s, dt=0.005, nt=20000, so 100 sec of simulation time). A visualization is available here; the USGS Bay Area region is in green, and the CCA-06 region is in red. Note that the USGS region has a GTL but the CCA region does not.

We added the Ely GTL to the CCA-06 model for this region and reran the point-source simulation (with additional filtering). A visualization is available here.

Below are plots comparing the surface without and with the Ely GTL on CCA-06.

No GTL, surface plot
GTL, surface plot

Alternative Velocity Model Plots

We have updated the CyberShake 18.5 velocity model to tile USGS Bay Area, CCA06, and CVM-S4.26, and a 1D background model. Also we have added the Ely GTL to the models. Then, we extracted horizontal cross-sections at 0 km, 0.1 km, 1 km, and 10 km. The 0 km cross-section also indicates the vertical cross-section locations. The following plots represent a proposed Northern California Velocity Model. There is no smoothing between models in these plots. Smoothing will be done to the final selected collection of CVMs.Thes plots were created using an updated version of the UCVM Software,which is available on a development branch in the ucvmc github repository.

The tiling order of velocity models in these plots is:

Science Name (ucvmc abbreviation):

  1. USGS Bay Area Model (cencal)
  2. CCA06 (cca)
  3. CVM-S4.26 (cvms5)
  4. Modified Hadley Kanamori 1D (1d)


Tiled without adding Ely-Jordan GTL to CCA06 or CVM-S4.26

0 km depth
0.1 km depth
1 km depth
10 km depth

Tiled with Ely-Jordan Vs30-based GTL added to CCA06, and CVM-S4.26

0 km depth
0.1 km depth
1 km depth
10 km depth

Tiled with Ely-Jordan Vs30-based GTL added to CCA06 and CVM-S4.26

x index=1500
x index=3000
y index=1600
y index=3600
y index=5600
y index=7600
y index=9600

Depth profiles of 2 selected points:

  • Point in CCA06 Model (38.3 -118.0 ):
with GTL
without GTL
  • Point in CVM-S4.26 (35.3 -115.5) :
with GTL
without GTL


Original Vs cross-sections

We have extracted horizontal cross-sections at 0 km, 0.1 km, 1 km, and 10 km. The 0 km cross-section also indicates the vertical cross-section locations.

0 km depth
0.1 km depth
1 km depth
10 km depth

We extracted vertical cross-sections along 5 cuts parallel to the x-axis:

  • Y index=1600: (38.929900, -124.363400) to (41.030000, -119.880200)
  • Y index=3600: (37.413200, -123.140900) to (39.470700, -118.713500)
  • Y index=5600: (35.884300, -121.967300) to (37.900400, -117.598200)
  • Y index=7600: (34.344500, -120.838200) to (36.319900, -116.529600)
  • Y index=9600: (32.794700, -119.750000) to (34.730300, -115.503600)

The southeast edge is on the left side of the plots.

y index=1600
y index=3600
y index=5600
y index=7600
y index=96006

and 2 cuts parallel to the y-axis:

  • X index=1500: (40.866500, -123.900300) to (32.207800, -117.529700)
  • X index=3000: (41.579900, -122.388500) to (32.844200, -116.127900)

The northwestern edge is on the left of the plots.

y index=1500
y index=3000

Verification

Performance Enhancements (over Study 17.3)

Computational and Data Estimates

Computational Estimates

In producing the computational estimates, we selected the four N/S/E/W extreme sites in the box which 1)within the 200 km cutoff for southern SAF events (381 sites) and 2)were outside the cutoff (488 sites). We produced inside and outside averages and scaled these by the number of inside and outside sites.

We also modified the box to be at an angle of 30 degrees counterclockwise of vertical, which makes the boxes about 15% smaller than with the previously used angle of 55 degrees.

We scaled our results based on the Study 17.3 performance of site s975, a site also in Study 18.3, and the Study 15.4 performance of DBCN, which used a very large volume and 100m spacing.

SGT calculation
# Grid points #VMesh gen nodes Mesh gen runtime # GPUs SGT job runtime Titan SUs BW node-hrs
Inside cutoff, per site 23.1 billion 192 0.85 hrs 800 1.35 hrs 69.7k 2240
Outside cutoff, per site 10.2 billion 192 0.37 hrs 800 0.60 hrs 30.8k 990
Total 41.6M 1.34M

For the post-processing, we quantified the amount of work by determining the number of individual rupture points to process (summing, over all ruptures, the number of rupture variations for that rupture times the number of rupture surface points) and multiplying that by the number of timesteps. We then scaled based on performance of s975 from Study 17.3, and DBCN in Study 15.4.

Below we list the estimates for Blue Waters or Titan.

PP calculation
#Points to process #Nodes (BW) BW runtime BW node-hrs #Nodes (Titan) Titan runtime Titan SUs
Inside cutoff, per site 5.96 billion 120 9.32 hrs 1120 240 10.3 hrs 74.2k
Outside cutoff, per site 2.29 billion 120 3.57 hrs 430 240 3.95 hrs 28.5k
Total 635K 42.2M

One potential computational plan is to split the SGT calculations 25% BW/75% Titan, and split the PP the other way: 75% BW, 25% Titan. With a 20% margin, this would require 50.17M SUs on Titan, and 973K node-hrs on Blue Waters.

Currently we have 91.7M SUs available on Titan (expires 12/31/18), and 8.14M node-hrs on Blue Waters (expires 8/31/18). Based on the 2016 PRAC (spread out over 2 years), we budgeted approximately 6.2M node-hours for CyberShake on Blue Waters this year, of which we have used 0.01M.

Data Estimates

SGT size estimates are scaled based on the number of points to process.

Data estimates
#Grid points Velocity mesh SGTs size Temp data Output data
Inside cutoff, per site 23.1 billion 271 GB 410 GB 1090 GB 19.1 GB
Outside cutoff, per site 10.2 billion 120 GB 133 GB 385 GB 9.3 GB
Total 158 TB 216 TB 589 TB 11.6 TB

If we plan on all the SGTs on Titan and split the PP 25% Titan, 75% Blue Waters, we will need:

Titan: 589 TB temp files + 3 TB output files = 592 TB

Blue Waters: 162 TB SGTs + 9 TB output files = 171 TB

SCEC storage: 1 TB workflow logs + 11.6 TB output data files = 12.6 TB(45 TB free)

Database usage: (4 rows PSA [@ 2, 3, 5, 10 sec] + 12 rows RotD [RotD100 and RotD50 @ 2, 3, 4, 5, 7.5, 10 sec])/rupture variation x 225K rupture variations/site x 869 sites = 3.1 billion rows x 125 bytes/row = 364 GB (2.0 TB free on moment.usc.edu disk)


Production Checklist

Presentations, Posters, and Papers

Related Entries