Difference between revisions of "CyberShake Study 24.8"

Latest revision as of 19:28, 30 October 2024

CyberShake Study 24.8 is a study in Northern California which includes deterministic low-frequency (0-1 Hz) and stochastic high-frequency (1-50 Hz) simulations. We will use the Graves & Pitarka (2022) rupture generator and the high frequency modules from the SCEC Broadband Platform v22.4. This study includes vertical component seismograms, period-dependent durations, and Fourier spectra IMs, and a reduction in minimum Vs to 400 m/s.

1 Status
2 Data Products
3 Science Goals
4 Technical Goals
5 Sites
6 Ruptures to Include
- 6.1 Source Contribution Curves
- 6.2 Disaggregations
7 Velocity Model
- 7.1 Primary 3D model
- 7.2 Potential modification to gabbro regions
- 7.3 Background model
- 7.4 Cross-sections
- 7.5 Candidate Model (RC1)
- 7.6 Vp/Vs Ratio Adjustment
- 7.7 Candidate Model (RC2)
8 Strain Green Tensors
9 Vertical Component
10 Rupture Generator
11 High-frequency codes
12 Hazard Curve Tests
- 12.1 Results using velocity model RC1
  - 12.1.1 Low-frequency curves
  - 12.1.2 High-frequency curves
- 12.2 Results using velocity model RC2
13 Updates and Enhancements
14 Output Data Products
- 14.1 File-based data products
  - 14.1.1 Deterministic
  - 14.1.2 Broadband
- 14.2 Database data products
  - 14.2.1 Deterministic
  - 14.2.2 Broadband
- 14.3 Hazard products
- 14.4 Data products after the study
15 Computational and Data Estimates
- 15.1 Computational Estimates
- 15.2 Data Estimates
16 Lessons Learned
17 Stress Test
- 17.1 Changes from stress test
- 17.2 Stress test results
18 Events During Study
- 18.1 Renewal of Globus consents
- 18.2 Restarts of the rvgahp daemons
19 Performance Metrics
20 Production Checklist
21 Presentations, Posters, and Papers
22 References

Status

This study is underway. As of 10/30/24, it is 53.3% complete.

The low-frequency calculations finished on 10/30/24.

Data Products

A link to available data products will be posted here when the study completes.

Science Goals

The science goals for this study are:

To perform an updated broadband study for the greater Bay Area.
To use an updated rupture generator and improved velocity model from Study 18.8.
To use the same parameters as in Study 22.12 when possible to make comparisons between the studies simple.

Technical Goals

The technical goals for this study are:

Use Frontier for the SGTs and Frontera for the post-processing and high-frequency calculations.
Use a modified approach for the production database, to improve performance.

Sites

For this study, we chose to focus on a smaller region than in Study 18.8. Starting with the Study 18.8 region, we selected a smaller (180 km x 100 km) box extending roughly from San Jose to Santa Rosa, containing 315 sites.

Ruptures to Include

Summary: we decided to exclude the southern San Andreas events from Study 24.8. This was implemented by creating a new ERF with ID 64, which includes all the ERF 36 ruptures except for the southern San Andreas events.

Historically, we have determined which ruptures to include in a CyberShake run by calculating the distance between the site and the closest part of the rupture surface. If that distance is less than 200 km, we then include all ruptures which take place on that surface, including ruptures which may extend much farther away from the site than 200 km.

For Northern California sites, this means that sites around San Jose and south include southern San Andreas events (events which rupture the northernmost segment of the southern San Andreas) within 200 km. Since there are some UCERF2 ruptures which extend from the Parkfield segment all the way down to Bombay Beach, the simulation volumes for some of these Northern California sites cover most of the state. This was the case for Study 18.8 (sample volumes can be seen on this page). This required tiling together 3 3D models and a background 1D model.

To simplify the velocity model and reduce the volumes, we are investigating omitting southern San Andreas events from this study.

Source Contribution Curves

Below are source contribution curves for 3 sites: s3430 (southwest corner of the study region), s3446 (southeast corner of the study region), and SJO (San Jose). In general, the sSAF events are about the 3rd largest contributor at long periods and medium-to-long return periods.

Site	2 sec	3 sec	5 sec	10 sec
s3430
s3446
SJO

We also looked at the source contributions for these 3 sites from ASK 2014. In general, the sSAF events play a reduced role compared to the CyberShake results.

Site	2 sec	3 sec	5 sec	10 sec
s3430
s3446
SJO

Disaggregations

From Study 18.8, we looked at disaggregations for s3430, s3446, and SJO at 1e-3 (1000 yr), 4e-4 (2500 yr), and 1e-4 (10000 yr) probability levels, at 2 and 10 seconds. We list the top 3 contributing sources from the southern SAF, their magnitude ranges, and their contributing percentages.

The only significant contributions are for site s3446 at 10 second period. Those come from large events, with median magnitude 7.85 or higher.

s3430

Period	1e-3	4e-4	1e-4
2 sec	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
10 sec	86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 0.01% 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.01% 85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), <0.01%	89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), <0.01% 80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%

s3446

Period	1e-3	4e-4	1e-4
2 sec	84 (S. San Andreas;PK+CH+CC+BB+NM, M7.45-7.95), <0.01% 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), <0.01% 80 (S. San Andreas;PK, M5.65-6.35), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
10 sec	85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 6.83% 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 4.18% 84 (S. San Andreas;PK+CH+CC+BB+NM, M7.45-7.95), 1.53%	85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 4.27% 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 3.09% 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 1.08%	86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 1.19% 85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 1.19% 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.55%

SJO

Period	1e-3	4e-4	1e-4
2 sec	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
10 sec	85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 0.09% 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 0.07% 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.05%	89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.01% 88 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG, M7.75-8.35), 0.01% 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), <0.01%	80 (S. San Andreas;PK, M5.65-6.35), <0.01% 81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01% 82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%

Velocity Model

We will perform validation of the proposed velocity model using northern California BBP events.

To line up closely with the USGS SF model angle, we will generate volumes using an angle of -36 degrees.

For generating sample meshes, we will use site s3446, a site in the SE corner of the study region with one of the larger volumes.

Simulation region for s3446 is in yellow. Also plotted are the extents of the USGS SF model, the USGS regional model, CCA-06, and CVM-S4.26.M01.

Primary 3D model

Given the extensive low-velocity near-surface regions in the USGS SF CVM, we plan to use a minimum Vs of 400 m/s (and therefore a grid spacing of 80 m).

Initial slices with the USGS SF CVM are available here: UCVM_sfcvm_geomodelgrid. We found two sharply defined high-velocity patches visible on the surface slice, one in the East Bay near the mountains, and another near Gilroy. These are regions where the gabbro type goes to the surface, and so the SF CVM geological rules dictate that the high velocities go to the surface as well.

These patches are not present in the Vs30 models - for instance, for the point (37.6827, -122.086) SF CVM gives a surface Vs of about 3500 m/s, but Wills (2015) has Vs30=710 and Thompson (2018) has Vs30=702.

Potential modification to gabbro regions

A candidate modification to the gabbro regions to reduce the near-surface velocities is to apply the approach used by Arben Pitarka and Rie Nakata, detailed below.

Component	At surface	At 7.75 km depth	derivation
Vp	4.2 km/s	5.7 km/s	Linear interpolation
Vs	2.44 km/s	3.4 km/s	Vp/Vs relationship
Density	2.76 g/cm3	2.87 g/cm3	Vp/Density relationship

The Vs (km/s) values are derived from Vp (km/s) using the San Leandro Gabbro relationship:

Vs = 0.7858 - 1.2344*Vp + 0.7949*Vp^2 - 0.1238*Vp^3 + 0.0064*Vp^4

The density (g/cm3) values are derived from Vp (km/s) using the San Leandro Gabbro relationship:

density = 2.4372 + 0.0761*Vp

A sample plot is below.

Nakata and Pitarka modification slice.png

Background model

There are several candidates to use as a background model for the regions outside of the 3D model region.

1D models

1D Broadband Platform model - either Northern California, Central California, or the Southern Sierras.
1D CVM-S4 background model
Extend eastern edge of SFCVM model to fill the remaining volume
1D CCA model (derived from averaging CCA-06), used in Study 17.3

3D models

3D CANVAS long-period tomography model
3D National Crustal model

Plots of these options are available below.

1D Model	BBP NorCal	BBP CenCal	BBP SouthernSierras	CVM-S4.26.M01 1D background	CCA 1D
Plot

Cross-sections

Cross-sections, no smoothing, CVM-S4.26.M01 1D background

Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01. This model was extracted on 2/28/24, and is one of the largest volumes needed for the study.

0m	80m	800m	2000m	4000m	10000m

Below are vertical cross-sections taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01. This model was extracted on 2/28/24, and is one of the largest volumes needed for the study.

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Cross-sections, smoothing, CVM-S4.26.M01 1D background

Below are horizontal cross-sections at various depths taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01. This model was extracted on 2/28/24.

0m	80m	800m	2000m	4000m	10000m

Below are vertical cross-sections taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01. This model was extracted on 2/28/24.

File:S3446 smoothed cross section locations.png

600px

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Cross-sections, no smoothing, Southern Sierra BBP 1D background

Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, Southern Sierra BBP1D model. This model was extracted on 3/13/24.

0m	80m	800m	2000m	4000m	10000m

Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, Southern Sierra BBP1D model. This model was extracted on 3/13/24.

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Cross-sections, no smoothing, extended SFCVM Sierra 1D background, CCA + taper

Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM. This model was extracted on 4/2/24.

0m	80m	800m	2000m	4000m	10000m

Below are vertical cross-sections.

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Cross-sections, smoothing, extended SFCVM Sierra 1D background, CCA + taper

Below are horizontal cross-sections at various depths taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM. This model was extracted on 4/2/24.

0m	80m	800m	2000m	4000m	10000m

Below are vertical cross-sections.

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Cross-sections, no smoothing, extended SFCVM Sierra 1D background with taper, CCA + taper

Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM + taper. This plot includes our typical practice of populating the surface point by querying the models at a depth of grid_spacing/4, or 20m. This model was extracted on 4/9/24.

Surface (20m)	80m	800m	2000m	4000m	10000m

Y=2400	Y=4800	Y=7200

X=1400	X=2800

Candidate Model (RC1)

Our candidate model is generated using (1) SFCVM with the gabbro modifications; (2) CCA-06 with the merged taper in the top 700m; (3) the NC1D model with the merged taper in the top 700m.

Surface (20m)	80m	800m	2000m	4000m	10000m

Vp/Vs Ratio Adjustment

For this study, we are modifying our approach to preserving the Vp/Vs ratio when applying a Vs floor to avoid very large Vp/Vs ratios.

Our previous approach for applying the Vs floor is as follows:

If Vs < Vs_floor (400 m/s):
1. Calculate the Vp/Vs ratio
2. Change Vs to the floor
3. Calculate a new Vp using Vp = Vs_floor * Vp/Vs ratio
Apply Vp and density floors

However, there are some sites with very high Vp/Vs ratios near the surface where Vs is low. Therefore, if this algorithm is applied, unexpectedly high Vp values may result.

Here is a vertical profile at site s3240 (Moffett Field). You can see the high surface Vp value:

Looking in more detail, here are the Vp and Vs values in the top 90m at s3240:

Depth (m)	Vp	Vs	Vp/Vs ratio	Adjusted Vs	Adjusted Vp
0	739	81	9.12	400	3649
10	1009	82	12.30	400	4922
20	1309	84	15.58	400	6233
30	1502	152	9.88	400	3953
40	1590	285	5.58	400	3649
50	1678	418	4.01
60	1711	436	3.92
70	1744	453	3.85
80	1776	471	3.77
90	1807	489	3.70

Since we are using 80m grid spacing, and populating the surface point at a depth of (grid spacing)/4 = 20m, the values at 20m and 80m are being used. The very high Vp/Vs ratio at 20m means that a very high Vp value is used.

These high Vp/Vs ratios occur at a number of locations around San Francisco Bay, illustrated in the surface Vp plot below:

To solve this problem, we will modify the process for applying the Vs floor. We will use the Vp/Vs ratio at 80m depth instead of at the surface, and use a maximum ratio of 4. A similar process was used in the HighF project.

If Vs < Vs_floor (400 m/s):
1. If surface grid point:
  1. Calculate Vp/Vs ratio at 1 grid point depth (80m)
  2. If Vp/Vs ratio > 4:
    1. Lower Vp/Vs ratio to 4
2. Else:
  1. Calculate Vp/Vs ratio at this grid point
3. New Vs = Vs_floor
4. New Vp = Vs * (potentially modified) Vp/Vs ratio.
Apply Vp and density floors.

Below is a surface Vp plot with the ratio modification. Note that the areas of previous high Vp have been reduced.

Candidate Model (RC2)

Candidate model RC2 is generated using the following procedure:

Tiling with:
1. USGS SFCVM v21.1
2. CCA-06
3. 1D background model, derived as an extension of the Sierra section of the SFCVM model and described here.
Surface points are populated using a depth of (grid spacing)/4, which is 20m for these meshes.
An Ely-Jordan taper is applied to the top 700m across all models using Vs30 values from Thompson et al. (2020).
Application of a Vs floor of 400 m/s, using the procedure outlined in CyberShake_Study_24.8#Vp/Vs Ratio Adjustment.
Smoothing is applied within 20km of a model boundary.

Vs plots:

Surface (20m)	80m	160m	320m	640m	2000m	4000m	10000m

Surface Vp plot:

Strain Green Tensors

We will use the HIP implementation of AWP-ODC-SGT, with the following parameters:

Grid spacing: 80 m
DT: 0.004 sec
NT: 50000 timesteps by default, increased to 75000 for sites with any site-to-hypocenter distance greater than 450 km.
Minimum Vs: 400 m/s

SGTs will be saved with a time decimation of 10, so every 0.04 sec.

Vertical Component

We will include vertical (Z) component seismograms in this study. To support this, we will produce Z-component SGTs and include Z-component synthesis in the post-processing and broadband stages.

Verification that the Z component codes are working correctly is documented at Vertical component verification.

Rupture Generator

We will use the same version of the rupture generator that we used for Study 22.12, v5.5.2.

To match the SGT timestep, SRFs will be generated with dt=0.04s, deterministic seismograms will be output with dt=0.04s, and broadband seismograms will use dt=0.01s.

High-frequency codes

We will use the Graves & Pitarka high-frequency codes from the BBP v22.4.

However, since we are using a denser mesh (80m) and a lower minimum Vs (400 m/s), we will not apply site correction to the low-frequency seismograms before combining. Rob states, You may recall that there is a klugy process we have used to estimate the Vref value based on the Vsmin and grid spacing of the model. But, it has only been applied for the case of h=100 m and Vsmin=500 m/s. What I found here is that estimating Vref using the 80m & 400m/s model is that Vref is almost always less than Vs30 (i.e., Vsite). This means that when the site adjustment is applied, the motions are deamplified. This is why we see such a poor fit for the 3D case when using the estimated Vref values. My conclusion at this point is that if we run the 3D calculation with 80 m grid spacing and Vsmin of 400 m/s (or lower), then we probably do not need to apply any site adjustments.

Hazard Curve Tests

We are calculating test hazard curves for the following sites:

Results using velocity model RC1

Low-frequency curves

Site	2 sec	3 sec	5 sec	10 sec	Vertical profile
s3446

s3240

ALBY

SJO

CFCS

s3171

CSUEB

CSU1

SFRH

LVMR

HAYW

High-frequency curves

Site	1 sec	0.5 sec	0.2 sec	0.1 sec	Vertical profile
s3446
s3240
ALBY
SJO
CFCS
s3171
CSUEB
CSU1
SFRH
LVMR
HAYW

Results using velocity model RC2

Low-frequency curves

Site	2 sec	3 sec	5 sec	10 sec	Vertical profile
s3240

ALBY

SJO

CFCS

s3171

CSUEB

CSU1

SFRH

LVMR

HAYW

Comparisons with Study 18.8

Study 18.8 curves are in red, and new curves are in black.

Site	2 sec	3 sec	5 sec	10 sec	Vertical profile
s3240
ALBY
SJO
CFCS
s3171
CSUEB
CSU1
SFRH
LVMR
HAYW

High-frequency curves

Site	1 sec	0.5 sec	0.2 sec	0.1 sec	Vertical profile
s3240
ALBY
SJO
CFCS
s3171
CSUEB
CSU1
SFRH
LVMR
HAYW

Updates and Enhancements

Used smaller study region than in Study 18.8.
Removed southern San Andreas events, and created a new ERF.

Output Data Products

File-based data products

We plan to produce the following data products, which will be stored at CARC:

Deterministic

Seismograms: 3-component seismograms, 10000 timesteps (400 sec, dt=0.04s) each.
PSA: We are removing geometric mean PSA calculations from this study.
RotD: PGV, and RotD50, RotD100, and the RotD100 azimuth at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1)
Vertical response spectra at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
Durations: for X and Y components, energy integral, Arias intensity, cumulative absolute velocity (CAV), and for both velocity and acceleration, 5-75%, 5-95%, and 20-80%. Also, period-dependent acceleration 5-75%, 5-95%, and 20-80% for 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).

Broadband

Seismograms: 3-component seismograms, 40000 timesteps (400 sec, dt=0.01s) each.
PSA: We are removing geometric mean PSA calculations from this study.
RotD: PGA, PGV, and RotD50, RotD100, and the the RotD100 azimuth at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)
Vertical response spectra at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
Durations: for X and Y components, energy integral, Arias intensity, cumulative absolute velocity (CAV), and for both velocity and acceleration, 5-75%, 5-95%, and 20-80%. Also, period-dependent acceleration 5-75%, 5-95%, and 20-80% for 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)

Database data products

We plan to store the following data products in the database on moment-carc:

Deterministic

RotD50 for 6 periods (10, 7.5, 5, 4, 3, 2). Note that we are NOT storing RotD100.
Duration: acceleration 5-75% and 5-95% for both X and Y

Broadband

RotD50 for PGA, PGV, and 19 periods (10, 7.5, 5, 4, 3, 2, 1, 0.75, 0.5, 0.4, 0.3, 0.2, 0.1, 0.075, 0.05, 0.04, 0.03, 0.02, 0.01). Note that we are NOT storing RotD100.

Hazard products

For each site, we will produce hazard curves from the deterministic results at 10, 5, 3, and 2 seconds, and from the broadband results at 10, 5, 3, 2, 1, 0.5, 0.2, and 0.1 seconds.

When the study is complete, we will produce maps from the deterministic results at 10, 5, 3, and 2 seconds, and from the broadband results at 10, 5, 3, 2, 1, 0.5, 0.2, and 0.1 seconds.

Data products after the study

After the study completes, we plan to compute Fourier spectra for all 3 components:

For deterministic, at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
For broadband at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)

Computational and Data Estimates

Computational Estimates

We based these estimates on the test sites.

SGT calculation
	UCVM runtime	UCVM nodes	SGT runtime (3 components)	SGT nodes	Other SGT workflow jobs	SGT Total
Average of 11 test sites	761 sec	96	7134 sec	100	7200 node-sec	220 node-hrs

220 node-hrs/site x 315 sites + 10% overrun = 76,230 node-hours for SGT workflows on Frontier.

PP calculation
	DirectSynth runtime	DirectSynth nodes	Additional runtime for period-dependent calculation	PP Total
75th percentile of 10 test sites	13914 sec	60	61938 core-sec	232.2 node-hrs

BB calculation
	BB runtime	BB nodes	Additional runtime for period-dependent calculation	BB Total
75th percentile of 10 test sites	8019 sec	40	61938 core-sec	89.4 node-hrs

(232.2+89.7) node-hrs/site x 315 sites + 10% overrun = 111,500 node-hours for PP and BB calculations on Frontera.

Data Estimates

We use the 75th percentile estimate of 206,500 rupture variations.

We are generating 3-component SGTs and 3-component seismograms, with 10k timesteps (400 sec) for LF and 40k timesteps (400 sec) for BB.

Data estimates
	Velocity mesh	SGTs size	Temp data	LF Output data	BB Output data	Total output data
Per site, derived from 10 site average (GB)	359	1131	1490	23.7	93.6	117.3
Total for 335 sites (TB)	110	348	458	7.3	28.8	36.1

CARC

We estimate 117.3 GB/site x 315 sites = 36.1 TB in output data, which will be transferred back to CARC. We currently have 29 TB free.

shock-carc

We estimate (3 MB SGT + 32 MB PP + 219 MB BB logs + 3 MB output products) x 315 sites = 79 GB in workflow log space on /home/shock. This drive has approximately 1.2 TB free.

moment-carc database

The PeakAmplitudes table uses approximately 183 bytes for data + 179 bytes for index = 363 bytes per entry.

362 bytes/entry * 35 entries/event (10 det + 25 stoch) * 206,500 events/site * 315 sites = 768 GB. The drive on moment-carc with the mysql database has 6.6 TB free.

Lessons Learned

Stress Test

For the stress test, we will run the first 20 sites and check for scientific and technical issues.

Usage before the stress test:

On Frontier, 587,856 of 700,000 node-hours for project GEO156. callag has used 22,166 node-hours.
On Frontera, 316,715 of 600,000 node-hours for project EAR20006. scottcal has used 11,274 node-hours.

The stress test began on 8/27/24 at 11:25:23 PDT.

To help us finish the stress test before the SCEC AM, TACC granted us a Frontera reservation for 200 nodes for 8 days, beginning on 8/28/24 at 8 am PDT. We didn't realized we needed to specify the --reservation tag, so we began utilizing it around 9 am PDT.

We gave the reservation back in the morning of 8/30. After the stress test, callag had used 32,660 node-hours on Frontier and scottcal used 18,493 node-hours on Frontera.

Stress test computational cost:

SGTs: 10494/20 sites = 524.7 node-hours per site, about 2.4x what we estimated. This is mostly due to having used meshes with a -55 degree angle, resulting in larger meshes requiring more computation time.
PP and BB: 370.0 node-hours per site, about 15% more than we estimated.

Changes from stress test

Based on the stress test, we made the following changes:

Reduced ramp-up time for DirectSynth worker processes.
Fixed issue with PGV writing to files in the BB codes.
Changed mesh angle from -55 to -36 degrees.
Changed smoothing zone from 10 km on either side of the boundary to 20 km.
Fixed issue with vertical response and period duration files not automatically transferred.
Discovered issue with accessing moment-carc through the USC VPN - confirmed that neither Xiaofeng nor Kevin can access it.

Stress test results

Below are hazard curves for the 20 test sites in the stress test. A KML file with the stress test sites is available here.

Low-frequency

These curves (in black) include comparisons with Study 18.8 (in red)

Site	2 sec	3 sec	5 sec	10 sec
s3240
ALBY
SJO
CFCS
s3171
CSUEB
CSU1
SFRH
LVMR
HAYW
s3446
NAPA
SRSA
MSRA
PTRY
DALY
SSOL
LICK
SSFO
BLMT

Sites with notable differences

We identified 3 sites with notable differences between Study 24.8 and Study 18.8:

LVMR is higher at 10 sec
CFCS is higher 2, 3, 5 sec
s3171 is lower at 3, 5, 10 sec

We believe the difference in LVMR is due to the expanded basin added in SFCVM v21.1, and s3171 can be explained by the change in profile as well:

Site	Profile, SFCVM v21.1	Profile, Cencal model used in Study 18.8
LVMR
s3171

A scatterplot comparing the average 2 sec RotD50 value for each rupture shows that the Study 24.8 results are consistently higher than the 18.8 results for CFCS:

We extracted vertical slices for the top from Cencal (floor = 500 m/s) and the Study 24.8 model (taper, floor = 400 m/s) for the top 5000 m along an east-west line running through CFCS.

Vertical slice, Study 24.8	Vertical slice, Cencal

Corrected Study 18.8 comparisons

In an attempt to replicate the Study 18.8 results, we discovered that the Study 18.8 velocity models were tiled in a different order than for Study 24.8: CCA-06, then CenCal, then CVM-S4.26.M01, as described here. Several of the stress test sites fall within the 20 km smoothing zone surrounding the Study 18.8 CCA-06/Cencal interface (interface in blue, 20km zone in white):

We compared the velocity profiles of Study 24.8 and the correct Study 18.8 configuration for the 5 stress test sites. For CFCS, this explains the sharp increase in hazard. The Study 18.8 profile is in blue, and the Study 24.8 profile is in orange.

Site	Vs overlay, top 700m	2 sec curve	3 sec curve	5 sec curve	10 sec curve
CFCS
SJO
s3446
BLMT
LICK

Impact of rotation angle and smoothing zone

Based on the below analysis, we will rerun the stress test sites with the intended angle of -36 degrees and a 20 km smoothing zone so that all Study 24.8 results will be consistent.

We discovered that the stress test sites were run with a volume rotation angle of -55 degrees and a smoothing zone width of 10 km on either side of the interface. This is different from our intended rotation angle of -36 degrees and smoothing zone width of 20 km. To quantify the impact of this, we ran CFCS with the updated values. Comparisons are below. The black curves are the stress test run, the blue curves are the corrected run.

2 sec	3 sec	5 sec	10 sec

Events During Study

The main study began on 9/24/24 at 11:49:59 PDT.

We began with a maximum of 5 workflows on Frontier and 20 on Frontera. Later on 9/24 we increased the number of Frontier workflows to 15.

On 9/30, moment-carc wasn't passed to the Check Duration job for finishing PP workflows. I updated the dax generator to correctly pass through the desired database for this job.

On 9/30, I ran out of /home quota on Frontera. This was an issue because some of the rvGAHP-related logs are written here, and it resulted in "Failed to start transfer GAHP" errors. I cleaned up some space on /home and released the jobs.

On 9/30, the merge_pmc jobs were held because they still included the stress test reservation on Frontera. I removed the reservation string and released the jobs.

On 10/1, I found that the cronjob on Frontier to monitor job usage was removed from the crontab, so I added it back.

On 10/2, I turned off stochastic calculations on Frontera while we investigated the unexpected BB results from the stress test.

On 10/10, the work2 filesystem on Frontera, where the executables and rupture files are hosted, had a problem, causing all the Frontera jobs to be held. Additionally, login4, the host which connects to shock, was unavailable. When login4 returned we restarted the rvGAHP process.

On 10/16, the scottcal account was added to the CyberShake DesignSafe project. This meant that scottcal is now part of 3 allocations, leading to a Slurm error when jobs were submitted without specifying an account, meaning Condor jobs were held. I added the EAR20006 account to all Frontera jobs, and had to manually add it for jobs which were already planned.

On 10/16, I realized that DirectSynth jobs were requesting a wallclock time of 10 hours, but these jobs are usually only taking a bit more than 4. I changed the requested job length to 5 hours.

On 10/17, I discovered that the PP Error jobs were because the corresponding SGT workflow had finished its Update and Handoff jobs, but then the stage-out of the SGTs to Frontera failed because of Globus consents. The registration job is dependent on stage-out, so it didn't run either. Then, when the PP workflow tries to plan, it can't find a copy of the SGT files on Frontera and aborts. I couldn't use the standard CyberShake scripts to restart these workflows, since in the database they were already recorded as SGT Generated, so instead I just reran the pegasus-run commands in the log-plan* files.

On 10/18, I got an email from TACC staff that the jobs are causing too much load on the scratch filesystem, and a request to reduce the number of simultaneous jobs to 4. I reduced the number of Frontera slots to 4 in the workflow auto-submission tool, and am following up to learn the specifics of the problem and if there's a way to fix it.

SGT calculations on Frontier finished on 10/18/24 at 12:59:43 PDT.

On 10/21, the broadband transfers to Corral for Study 22.12 resulted in going over quota on CARC scratch1 again, interfering with the workflows for this study. I cleaned up scratch1 and fixed the issue.

On 10/28-30, the work2 filesystem and scheduler on Frontera had a number of issues, requiring restarts of the rvGAHP daemon and some work to recover the job state.

Renewal of Globus consents

We will track when we renew the Globus consents.

10/6

10/9

10/13

10/17

10/24

10/29

Restarts of the rvgahp daemons

We will track when we restart the rvgahp daemons on login10@frontier and login4@frontera.

10/9 on Frontera

10/10 on Frontera (node crashed)

10/29 on Frontera (filesystem issues)

10/30 on Frontera (continuing filesystem issues)

Performance Metrics

At the start of the main study, project geo156 on Frontier has used 609101 node-hours (of 700,000). User callag has used 33398 node-hours. Project EAR20006 has used 12925.147 node-hours (of 676,000). User scottcal has used 503.796 node-hours.

Production Checklist

~~Run test workflow against moment-carc.~~
~~Investigate velocity profile differences with Mei's plots (s3171 and HAYW)~~
~~Wrap period-dependent duration code and test in PP.~~
~~Wrap period-dependent duration code and test in BB.~~
~~Integrate period-dependent duration code into workflows.~~
~~Update data and compute estimates.~~
~~Determine where to copy output data.~~
~~Modify workflows to remove double-staging of SGTs to Frontera.~~
~~Schedule and hold readiness reviews with TACC and OLCF.~~
~~Modify workflows to only insert RotD50, not RotD100.~~
~~Science readiness review~~
~~Technical readiness review~~
~~Verify that vertical component response is being calculated correctly.~~
~~Set up cronjobs to monitor usage.~~
~~Solve issue with putting velocity parameters into the database from Frontier.~~
~~Tag code in github repository~~

Presentations, Posters, and Papers

References

@@ Line 1: / Line 1: @@
-CyberShake Study 24.1 is an upcoming study in Northern California which includes deterministic low-frequency (0-1 Hz) and stochastic high-frequency (1-50 Hz) simulations.  We will use the [[Rupture_Variation_Generator_v5.5.2|Graves & Pitarka (2022)]] rupture generator and the high frequency modules from the SCEC Broadband Platform v22.4.
+CyberShake Study 24.8 is a study in Northern California which includes deterministic low-frequency (0-1 Hz) and stochastic high-frequency (1-50 Hz) simulations.  We will use the [[Rupture_Variation_Generator_v5.5.2|Graves & Pitarka (2022)]] rupture generator and the high frequency modules from the SCEC Broadband Platform v22.4.  This study includes vertical component seismograms, period-dependent durations, and Fourier spectra IMs, and a reduction in minimum Vs to 400 m/s.
 == Status ==
-This study is in the planning phase.  We hope to begin this study in January 2024.
+This study is underway.  As of 10/30/24, it is 53.3% complete.
+The low-frequency calculations finished on 10/30/24.
 == Data Products ==
+A link to available data products will be posted here when the study completes.
 == Science Goals ==
@@ Line 35: / Line 39: @@
 == Ruptures to Include ==
+<b>Summary: we decided to exclude the southern San Andreas events from Study 24.8.  This was implemented by creating a new ERF with ID 64, which includes all the ERF 36 ruptures except for the southern San Andreas events.</b>
 Historically, we have determined which ruptures to include in a CyberShake run by calculating the distance between the site and the closest part of the rupture surface.  If that distance is less than 200 km, we then include all ruptures which take place on that surface, including ruptures which may extend much farther away from the site than 200 km.
@@ Line 98: / Line 104: @@
 From Study 18.8, we looked at disaggregations for s3430, s3446, and SJO at 1e-3 (1000 yr), 4e-4 (2500 yr), and 1e-4 (10000 yr) probability levels, at 2 and 10 seconds.  We list the top 3 contributing sources from the southern SAF, their magnitude ranges, and their contributing percentages.
-s3430
+The only significant contributions are for site s3446 at 10 second period.  Those come from large events, with median magnitude 7.85 or higher.
-{|
+==== s3430 ====
+{| border="1" cellpadding="3"
 ! Period !! 1e-3 !! 4e-4 !! 1e-4
 |-
 ! 2 sec
-| 80 (S. San Andreas;PK, M5.65-6.35), 0%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), 0%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), 0%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
 |-
 ! 10 sec
+| 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 0.01%<br/>89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.01%<br/>85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), <0.01%
+| 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), <0.01%<br/>80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
 |}
-s3446
+==== s3446 ====
-{|
+{| border="1" cellpadding="3"
 ! Period !! 1e-3 !! 4e-4 !! 1e-4
 |-
 ! 2 sec
+| 84 (S. San Andreas;PK+CH+CC+BB+NM, M7.45-7.95), <0.01%<br/>89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), <0.01%<br/>80 (S. San Andreas;PK, M5.65-6.35), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
 |-
 ! 10 sec
+| 85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 6.83%<br/>86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 4.18%<br/>84 (S. San Andreas;PK+CH+CC+BB+NM, M7.45-7.95), 1.53%
+| 85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 4.27%<br/>86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 3.09%<br/>89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 1.08%
+| 86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 1.19%<br/>85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 1.19%<br/>89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.55%
 |}
-SJO
+==== SJO ====
-{|
+{|border="1" cellpadding="3"
 ! Period !! 1e-3 !! 4e-4 !! 1e-4
 |-
 ! 2 sec
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
 |-
 ! 10 sec
+| 85 (S. San Andreas;PK+CH+CC+BB+NM+SM, M7.55-8.15), 0.09%<br/>86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), 0.07%<br/>89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.05%
+| 89 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG+CO, M7.75-8.45), 0.01%<br/>88 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB+SSB+BG, M7.75-8.35), 0.01%<br/>86 (S. San Andreas;PK+CH+CC+BB+NM+SM+NSB, M7.65-8.25), <0.01%
+| 80 (S. San Andreas;PK, M5.65-6.35), <0.01%<br/>81 (S. San Andreas;PK+CH, M6.75-7.35), <0.01%</br>82 (S. San Andreas;PK+CH+CC, M7.15-7.65), <0.01%
 |}
 == Velocity Model ==
+We will perform validation of the proposed velocity model using northern California BBP events.
+To line up closely with the USGS SF model angle, we will generate volumes using an angle of -36 degrees.
+For generating sample meshes, we will use site s3446, a site in the SE corner of the study region with one of the larger volumes.
+{|
+| [[File:s3446_erf64_volume.png|thumb|400px|Simulation region for s3446 is in <span style="color:#FFBB00">yellow</span>.  Also plotted are the extents of the <span style="color:darkgreen">USGS SF model</span>, the <span style="color:limegreen">USGS regional model</span>, <span style="color:blue">CCA-06</span>, and <span style="color:red">CVM-S4.26.M01</span>.]]
+|}
+=== Primary 3D model ===
+Given the extensive low-velocity near-surface regions in the USGS SF CVM, we plan to use a minimum Vs of 400 m/s (and therefore a grid spacing of 80 m).
+{|
+| [[File:Sfcvm_h0_2.png|thumb|400px]]
+|}
+Initial slices with the USGS SF CVM are available here: [[UCVM_sfcvm_geomodelgrid]].  We found two sharply defined high-velocity patches visible on the surface slice, one in the East Bay near the mountains, and another near Gilroy.  These are regions where the gabbro type goes to the surface, and so the SF CVM geological rules dictate that the high velocities go to the surface as well.
+{|
+| [[File:eastbay_high_vs_vertical_profile.png|thumb|400px]]
+|}
+These patches are not present in the Vs30 models - for instance, for the point (37.6827, -122.086) SF CVM gives a surface Vs of about 3500 m/s, but Wills (2015) has Vs30=710 and Thompson (2018) has Vs30=702.
+=== Potential modification to gabbro regions ===
+A candidate modification to the gabbro regions to reduce the near-surface velocities is to apply the approach used by Arben Pitarka and Rie Nakata, detailed below.
+{| border="1"
+! Component !! At surface !! At 7.75 km depth !! derivation
+|-
+! Vp
+| 4.2 km/s ||  5.7 km/s || Linear interpolation
+|-
+! Vs
+| 2.44 km/s || 3.4 km/s || Vp/Vs relationship
+|-
+! Density
+| 2.76 g/cm3 || 2.87 g/cm3 || Vp/Density relationship
+|}
+The Vs (km/s) values are derived from Vp (km/s) using the San Leandro Gabbro relationship:
+<pre>Vs = 0.7858 - 1.2344*Vp + 0.7949*Vp^2 - 0.1238*Vp^3 + 0.0064*Vp^4</pre>
+The density (g/cm3) values are derived from Vp (km/s) using the San Leandro Gabbro relationship:
+<pre>density = 2.4372 + 0.0761*Vp</pre>
+A sample plot is below.
+{|
+| [[File:Nakata_and_Pitarka_modification_slice.png|thumb|800px]]
+|}
+=== Background model ===
+There are several candidates to use as a background model for the regions outside of the 3D model region.
+<b>1D models</b>
+#1D Broadband Platform model - either Northern California, Central California, or the Southern Sierras.
+#1D CVM-S4 background model
+#Extend eastern edge of SFCVM model to fill the remaining volume
+#1D CCA model (derived from averaging CCA-06), used in Study 17.3
+<b>3D models</b>
+#3D CANVAS long-period tomography model
+#3D National Crustal model
+Plots of these options are available below.
+{|
+! 1D Model !! BBP NorCal || BBP CenCal !! BBP SouthernSierras !! CVM-S4.26.M01 1D background !! CCA 1D
+|-
+! Plot
+| [[File:nocal500.png|thumb|300px]]
+| [[File:centralcal500.png|thumb|300px]]
+| [[File:ssn2-500.png|thumb|300px]]
+| [[File:cvms426_1dbackground.png|thumb|300px]]
+| [[File:Cs_cca_ucvm_1d_all.png|thumb|300px]]
+|-
+|}
+=== Cross-sections ===
+==== Cross-sections, no smoothing, CVM-S4.26.M01 1D background ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01.  This model was extracted on 2/28/24, and is one of the largest volumes needed for the study.
+{|
+! 0m !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:s3446_0m_nosmooth_vs.png|thumb|250px]]
+| [[File:s3446_80m_nosmooth_vs.png|thumb|250px]]
+| [[File:s3446_800m_nosmooth_vs.png|thumb|250px]]
+| [[File:s3446_2000m_nosmooth_vs.png|thumb|250px]]
+| [[File:s3446_4000m_nosmooth_vs.png|thumb|250px]]
+| [[File:s3446_10000m_nosmooth_vs.png|thumb|250px]]
+|}
+Below are vertical cross-sections taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01.  This model was extracted on 2/28/24, and is one of the largest volumes needed for the study.
+{|
+| [[File:s3446_cross_section_locations.png|thumb|600px]]
+|}
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:s3446_x_2400_vs.png|thumb|400px]]
+| [[File:s3446_x_4800_vs.png|thumb|400px]]
+| [[File:s3446_x_7200_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:s3446_y_1400_vs.png|thumb|400px]]
+| [[File:s3446_y_2800_vs.png|thumb|400px]]
+|}
+==== Cross-sections, smoothing, CVM-S4.26.M01 1D background ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01.  This model was extracted on 2/28/24.
+{|
+! 0m !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:s3446_0m_smooth_vs.png|thumb|250px]]
+| [[File:s3446_80m_smooth_vs.png|thumb|250px]]
+| [[File:s3446_800m_smooth_vs.png|thumb|250px]]
+| [[File:s3446_2000m_smooth_vs.png|thumb|250px]]
+| [[File:s3446_4000m_smooth_vs.png|thumb|250px]]
+| [[File:s3446_10000m_smooth_vs.png|thumb|250px]]
+|}
+Below are vertical cross-sections taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06, CVM-S4.26.M01.  This model was extracted on 2/28/24.
+{|
+| [[File:s3446_smoothed_cross_section_locations.png|thumb|600px]]
+|}
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:s3446_x_2400_smoothed_vs.png|thumb|400px]]
+| [[File:s3446_x_4800_smoothed_vs.png|thumb|400px]]
+| [[File:s3446_x_7200_smoothed_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:s3446_y_1400_smoothed_vs.png|thumb|400px]]
+| [[File:s3446_y_2800_smoothed_vs.png|thumb|400px]]
+|}
+==== Cross-sections, no smoothing, Southern Sierra BBP 1D background ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, Southern Sierra BBP1D model.  This model was extracted on 3/13/24.
+{|
+! 0m !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:s3446_0m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+| [[File:s3446_80m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+| [[File:s3446_800m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+| [[File:s3446_2000m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+| [[File:s3446_4000m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+| [[File:s3446_10000m_nosmooth_ss_bbp1d_vs.png|thumb|250px]]
+|}
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06, Southern Sierra BBP1D model.  This model was extracted on 3/13/24.
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:s3446_x_2400_nosmooth_ss_bbp1d_vs.png|thumb|400px]]
+| [[File:s3446_x_4800_nosmooth_ss_bbp1d_vs.png|thumb|400px]]
+| [[File:s3446_x_7200_nosmooth_ss_bbp1d_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:s3446_y_1400_nosmooth_ss_bbp1d_vs.png|thumb|400px]]
+| [[File:s3446_y_2800_nosmooth_ss_bbp1d_vs.png|thumb|400px]]
+|}
+==== Cross-sections, no smoothing, extended SFCVM Sierra 1D background, CCA + taper ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM.  This model was extracted on 4/2/24.
+{|
+! 0m !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:s3446_0m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_80m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_800m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_2000m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_4000m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_10000m_nosmooth_sfcvm_extended_vs.png|thumb|250px]]
+|}
+Below are vertical cross-sections.
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:s3446_x_2400_nosmooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_x_4800_nosmooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_x_7200_nosmooth_sfcvm_extended_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:s3446_y_1400_nosmooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_y_2800_nosmooth_sfcvm_extended_vs.png|thumb|400px]]
+|}
+==== Cross-sections, smoothing, extended SFCVM Sierra 1D background, CCA + taper ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated with smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM.  This model was extracted on 4/2/24.
+{|
+! 0m !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:s3446_0m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_80m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_800m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_2000m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_4000m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+| [[File:s3446_10000m_smooth_sfcvm_extended_vs.png|thumb|250px]]
+|}
+Below are vertical cross-sections.
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:s3446_x_2400_smooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_x_4800_smooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_x_7200_smooth_sfcvm_extended_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:s3446_y_1400_smooth_sfcvm_extended_vs.png|thumb|400px]]
+| [[File:s3446_y_2800_smooth_sfcvm_extended_vs.png|thumb|400px]]
+|}
+==== Cross-sections, no smoothing, extended SFCVM Sierra 1D background with taper, CCA + taper ====
+Below are horizontal cross-sections at various depths taken from a model for s3446 generated without smoothing, with the tiling SFCVM, CCA-06 + taper, 1D representation of the Sierra foothills in SFCVM + taper.  This plot includes our typical practice of populating the surface point by querying the models at a depth of grid_spacing/4, or 20m.  This model was extracted on 4/9/24.
+{|
+! Surface (20m) !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:4_9 s3446_0m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+| [[File:4_9_s3446_80m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+| [[File:4_9_s3446_800m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+| [[File:4_9_s3446_2000m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+| [[File:4_9_s3446_4000m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+| [[File:4_9_s3446_10000m_nosmooth_sfcvm_extended_taper_vs.png|thumb|250px]]
+|}
+{|
+! Y=2400 !! Y=4800 !! Y=7200
+|-
+| [[File:4_9_s3446_x_2400_nosmooth_vs.png|thumb|400px]]
+| [[File:4_9_s3446_x_4800_nosmooth_vs.png|thumb|400px]]
+| [[File:4_9_s3446_x_7200_nosmooth_vs.png|thumb|400px]]
+|}
+{|
+! X=1400 !! X=2800
+|-
+| [[File:4_9_s3446_y_1400_nosmooth_vs.png|thumb|400px]]
+| [[File:4_9_s3446_y_2800_nosmooth_vs.png|thumb|400px]]
+|}
+=== Candidate Model (RC1) ===
+Our candidate model is generated using (1) SFCVM with the gabbro modifications; (2) CCA-06 with the merged taper in the top 700m; (3) the [[NC1D]] model with the merged taper in the top 700m.
+{|
+! Surface (20m) !! 80m !! 800m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:4_19 s3446_20m_smooth_RC1_vs.png|thumb|250px]]
+| [[File:4_19_s3446_80m_smooth_RC1_vs.png|thumb|250px]]
+| [[File:4_19_s3446_800m_smooth_RC1_vs.png|thumb|250px]]
+| [[File:4_19_s3446_2000m_smooth_RC1_vs.png|thumb|250px]]
+| [[File:4_19_s3446_4000m_smooth_RC1_vs.png|thumb|250px]]
+| [[File:4_19_s3446_10000m_smooth_RC1_vs.png|thumb|250px]]
+|}
+=== Vp/Vs Ratio Adjustment ===
+<b>For this study, we are modifying our approach to preserving the Vp/Vs ratio when applying a Vs floor to avoid very large Vp/Vs ratios.</b>
+Our previous approach for applying the Vs floor is as follows:
+#If Vs < Vs_floor (400 m/s):
+##Calculate the Vp/Vs ratio
+##Change Vs to the floor
+##Calculate a new Vp using Vp = Vs_floor * Vp/Vs ratio
+#Apply Vp and density floors
+However, there are some sites with very high Vp/Vs ratios near the surface where Vs is low.  Therefore, if this algorithm is applied, unexpectedly high Vp values may result.
+Here is a vertical profile at site s3240 (Moffett Field).  You can see the high surface Vp value:
+{|
+| [[File:s3240_vert_profile.png|thumb|400px]]
+|}
+Looking in more detail, here are the Vp and Vs values in the top 90m at s3240:
+{| border="1"
+! Depth (m) !! Vp !! Vs !! Vp/Vs ratio !! Adjusted Vs !! Adjusted Vp
+|-
+| 0 || 739 || 81 || 9.12 || 400 || 3649
+|-
+| 10 || 1009 || 82 || 12.30 || 400 || 4922
+|-
+| <b> 20 </b> || 1309 || 84 || 15.58 || <b> 400 </b> || <b> 6233 </b>
+|-
+| 30 || 1502 || 152 || 9.88 || 400 || 3953
+|-
+| 40 || 1590 || 285 || 5.58 || 400 || 3649
+|-
+| 50 || 1678 || 418 || 4.01
+|-
+| 60 || 1711 || 436 || 3.92
+|-
+| 70 || 1744 || 453 || 3.85
+|-
+| <b> 80 </b> || <b> 1776 </b> || <b> 471 </b> || 3.77
+|-
+| 90 || 1807 || 489 || 3.70
+|}
+Since we are using 80m grid spacing, and populating the surface point at a depth of (grid spacing)/4 = 20m, the values at 20m and 80m are being used.  The very high Vp/Vs ratio at 20m means that a very high Vp value is used.
+These high Vp/Vs ratios occur at a number of locations around San Francisco Bay, illustrated in the surface Vp plot below:
+{|
+| [[File:s3240_surface_vp.png|thumb|400px]]
+|}
+To solve this problem, we will modify the process for applying the Vs floor.  We will use the Vp/Vs ratio at 80m depth instead of at the surface, and use a maximum ratio of 4.  A similar process was used in the HighF project.
+#If Vs < Vs_floor (400 m/s):
+##If surface grid point:
+###Calculate Vp/Vs ratio at 1 grid point depth (80m)
+###If Vp/Vs ratio > 4:
+####Lower Vp/Vs ratio to 4
+##Else:
+###Calculate Vp/Vs ratio at this grid point
+##New Vs = Vs_floor
+##New Vp = Vs * (potentially modified) Vp/Vs ratio.
+#Apply Vp and density floors.
+Below is a surface Vp plot with the ratio modification.  Note that the areas of previous high Vp have been reduced.
+{|
+| [[File:s3240_modifiedratio_surface_vp.png|thumb|400px]]
+|}
+=== Candidate Model (RC2) ===
+Candidate model RC2 is generated using the following procedure:
+#Tiling with:
+##USGS SFCVM v21.1
+##CCA-06
+##1D background model, derived as an extension of the Sierra section of the SFCVM model and described [[NC1D|here]].
+#Surface points are populated using a depth of (grid spacing)/4, which is 20m for these meshes.
+#An Ely-Jordan taper is applied to the top 700m across all models using Vs30 values from Thompson et al. (2020).
+#Application of a Vs floor of 400 m/s, using the procedure outlined in [[CyberShake_Study_24.8#Vp/Vs Ratio Adjustment]].
+#Smoothing is applied within 20km of a model boundary.
+Vs plots:
+{|
+! Surface (20m) !! 80m !! 160m !! 320m !! 640m !! 2000m !! 4000m !! 10000m
+|-
+| [[File:8_5_s3446_20m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_80m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_160m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_320m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_640m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_2000m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_4000m_smooth_RC2_vs.png|thumb|250px]]
+| [[File:8_5_s3446_10000m_smooth_RC2_vs.png|thumb|250px]]
+|}
+Surface Vp plot:
+{|
+| [[File:8_5_s3446_20m_smooth_RC2_vp.png|thumb|250px]]
+|}
+== Strain Green Tensors ==
+We will use the HIP implementation of AWP-ODC-SGT, with the following parameters:
+*Grid spacing: 80 m
+*DT: 0.004 sec
+*NT: 50000 timesteps by default, increased to 75000 for sites with any site-to-hypocenter distance greater than 450 km.
+*Minimum Vs: 400 m/s
+SGTs will be saved with a time decimation of 10, so every 0.04 sec.
+== Vertical Component ==
+We will include vertical (Z) component seismograms in this study.  To support this, we will produce Z-component SGTs and include Z-component synthesis in the post-processing and broadband stages.
+Verification that the Z component codes are working correctly is documented at [[Vertical component verification]].
 == Rupture Generator ==
+We will use the same version of the rupture generator that we used for Study 22.12, v5.5.2.
+To match the SGT timestep, SRFs will be generated with dt=0.04s, deterministic seismograms will be output with dt=0.04s, and broadband seismograms will use dt=0.01s.
 == High-frequency codes ==
+We will use the Graves & Pitarka high-frequency codes from the BBP v22.4.
+However, since we are using a denser mesh (80m) and a lower minimum Vs (400 m/s), we will not apply site correction to the low-frequency seismograms before combining.  Rob states, <i>You may recall that there is a klugy process we have used to estimate the Vref value based on the Vsmin and grid spacing of the model. But, it has only been applied for the case of h=100 m and Vsmin=500 m/s. What I found here is that estimating Vref using the 80m & 400m/s model is that Vref is almost always less than Vs30 (i.e., Vsite). This means that when the site adjustment is applied, the motions are deamplified. This is why we see such a poor fit for the 3D case when using the estimated Vref values.  My conclusion at this point is that if we run the 3D calculation with 80 m grid spacing and Vsmin of 400 m/s (or lower), then we probably do not need to apply any site adjustments.</i>
+== Hazard Curve Tests ==
+We are calculating test hazard curves for the following sites:
+{|
+| [[File:Study_24.6_test_sites_map.png|thumb|600px]]
+|}
+=== Results using velocity model RC1 ===
+==== Low-frequency curves ====
+{|
+! Site !! 2 sec !! 3 sec !! 5 sec !! 10 sec !! Vertical profile
+|-
+! s3446
+| [[File:s3446_10676_2sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_3sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_5sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_10sec_RotD50.png|thumb|300px]]
+| [[File:s3446_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:s3446_10676_2sec_RotD50_log.png|thumb|300px]]
+| [[File:s3446_10676_3sec_RotD50_log.png|thumb|300px]]
+| [[File:s3446_10676_5sec_RotD50_log.png|thumb|300px]]
+| [[File:s3446_10676_10sec_RotD50_log.png|thumb|300px]]
+|-
+! s3240
+| [[File:s3240_10677_2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10677_3sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10677_5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10677_10sec_RotD50.png|thumb|300px]]
+| [[File:s3240_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:s3240_10677_2sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10677_3sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10677_5sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10677_10sec_RotD50_log.png|thumb|300px]]
+|-
+! ALBY
+| [[File:ALBY_10678_2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10678_3sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10678_5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10678_10sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:ALBY_10678_2sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10678_3sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10678_5sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10678_10sec_RotD50_log.png|thumb|300px]]
+|-
+! SJO
+| [[File:SJO_10683_2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10683_3sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10683_5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10683_10sec_RotD50.png|thumb|300px]]
+| [[File:SJO_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:SJO_10683_2sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10683_3sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10683_5sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10683_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CFCS
+| [[File:CFCS_10684_2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10684_3sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10684_5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10684_10sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CFCS_10684_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10684_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10684_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10684_10sec_RotD50_log.png|thumb|300px]]
+|-
+! s3171
+| [[File:s3171_10685_2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10685_3sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10685_5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10685_10sec_RotD50.png|thumb|300px]]
+| [[File:s3171_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:s3171_10685_2sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10685_3sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10685_5sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10685_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CSUEB
+| [[File:CSUEB_10687_2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10687_3sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10687_5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10687_10sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CSUEB_10687_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10687_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10687_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10687_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CSU1
+| [[File:CSU1_10686_2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10686_3sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10686_5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10686_10sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CSU1_10686_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10686_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10686_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10686_10sec_RotD50_log.png|thumb|300px]]
+|-
+! SFRH
+| [[File:SFRH_10681_2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10681_3sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10681_5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10681_10sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:SFRH_10681_2sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10681_3sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10681_5sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10681_10sec_RotD50_log.png|thumb|300px]]
+|-
+! LVMR
+| [[File:LVMR_10682_2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10682_3sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10682_5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10682_10sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:LVMR_10682_2sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10682_3sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10682_5sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10682_10sec_RotD50_log.png|thumb|300px]]
+|-
+! HAYW
+| [[File:HAYW_10679_2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10679_3sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10679_5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10679_10sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:HAYW_10679_2sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10679_3sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10679_5sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10679_10sec_RotD50_log.png|thumb|300px]]
+|}
+==== High-frequency curves ====
+{|
+! Site !! 1 sec !! 0.5 sec !! 0.2 sec !! 0.1 sec !! Vertical profile
+|-
+! s3446
+| [[File:s3446_10676_1sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_0.5sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_0.2sec_RotD50.png|thumb|300px]]
+| [[File:s3446_10676_0.1sec_RotD50.png|thumb|300px]]
+| [[File:s3446_vert_profile.png|thumb|250px]]
+|-
+! s3240
+| [[File:s3240_10689_1sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10689_0.5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10689_0.2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10689_0.1sec_RotD50.png|thumb|300px]]
+| [[File:s3240_vert_profile.png|thumb|250px]]
+|-
+! ALBY
+| [[File:ALBY_10694_1sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10694_0.5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10694_0.2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10694_0.1sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_vert_profile.png|thumb|250px]]
+|-
+! SJO
+| [[File:SJO_10695_1sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10695_0.5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10695_0.2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10695_0.1sec_RotD50.png|thumb|300px]]
+| [[File:SJO_vert_profile.png|thumb|250px]]
+|-
+! CFCS
+| [[File:CFCS_10693_1sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10693_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10693_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10693_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_vert_profile.png|thumb|250px]]
+|-
+! s3171
+| [[File:s3171_10688_1sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10688_0.5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10688_0.2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10688_0.1sec_RotD50.png|thumb|300px]]
+| [[File:s3171_vert_profile.png|thumb|250px]]
+|-
+! CSUEB
+| [[File:CSUEB_10691_1sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10691_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10691_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10691_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_vert_profile.png|thumb|250px]]
+|-
+! CSU1
+| [[File:CSU1_10692_1sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10692_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10692_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10692_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_vert_profile.png|thumb|250px]]
+|-
+! SFRH
+| [[File:SFRH_10690_1sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10690_0.5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10690_0.2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10690_0.1sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_vert_profile.png|thumb|250px]]
+|-
+! LVMR
+| [[File:LVMR_10696_1sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10696_0.5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10696_0.2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10696_0.1sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_vert_profile.png|thumb|250px]]
+|-
+! HAYW
+| [[File:HAYW_10697_1sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10697_0.5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10697_0.2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10697_0.1sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_vert_profile.png|thumb|250px]]
+|}
+=== Results using velocity model RC2 ===
+==== Low-frequency curves ====
+{|
+! Site !! 2 sec !! 3 sec !! 5 sec !! 10 sec !! Vertical profile
+|-
+! s3240
+| [[File:s3240_10708_2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10708_3sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10708_5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10708_10sec_RotD50.png|thumb|300px]]
+| [[File:s3240_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:s3240_10708_2sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10708_3sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10708_5sec_RotD50_log.png|thumb|300px]]
+| [[File:s3240_10708_10sec_RotD50_log.png|thumb|300px]]
+|-
+! ALBY
+| [[File:ALBY_10709_2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10709_3sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10709_5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10709_10sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:ALBY_10709_2sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10709_3sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10709_5sec_RotD50_log.png|thumb|300px]]
+| [[File:ALBY_10709_10sec_RotD50_log.png|thumb|300px]]
+|-
+! SJO
+| [[File:SJO_10710_2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10710_3sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10710_5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10710_10sec_RotD50.png|thumb|300px]]
+| [[File:SJO_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:SJO_10710_2sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10710_3sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10710_5sec_RotD50_log.png|thumb|300px]]
+| [[File:SJO_10710_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CFCS
+| [[File:CFCS_10711_2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10711_3sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10711_5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10711_10sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CFCS_10711_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10711_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10711_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CFCS_10711_10sec_RotD50_log.png|thumb|300px]]
+|-
+! s3171
+| [[File:s3171_10712_2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10712_3sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10712_5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10712_10sec_RotD50.png|thumb|300px]]
+| [[File:s3171_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:s3171_10712_2sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10712_3sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10712_5sec_RotD50_log.png|thumb|300px]]
+| [[File:s3171_10712_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CSUEB
+| [[File:CSUEB_10713_2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10713_3sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10713_5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10713_10sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CSUEB_10713_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10713_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10713_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CSUEB_10713_10sec_RotD50_log.png|thumb|300px]]
+|-
+! CSU1
+| [[File:CSU1_10714_2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10714_3sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10714_5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10714_10sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:CSU1_10714_2sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10714_3sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10714_5sec_RotD50_log.png|thumb|300px]]
+| [[File:CSU1_10714_10sec_RotD50_log.png|thumb|300px]]
+|-
+! SFRH
+| [[File:SFRH_10715_2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10715_3sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10715_5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10715_10sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:SFRH_10715_2sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10715_3sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10715_5sec_RotD50_log.png|thumb|300px]]
+| [[File:SFRH_10715_10sec_RotD50_log.png|thumb|300px]]
+|-
+! LVMR
+| [[File:LVMR_10715_2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10715_3sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10715_5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10715_10sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:LVMR_10715_2sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10715_3sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10715_5sec_RotD50_log.png|thumb|300px]]
+| [[File:LVMR_10715_10sec_RotD50_log.png|thumb|300px]]
+|-
+! HAYW
+| [[File:HAYW_10717_2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10717_3sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10717_5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10717_10sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_RC2_vert_profile.png|thumb|250px]]
+|-
+|
+| [[File:HAYW_10717_2sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10717_3sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10717_5sec_RotD50_log.png|thumb|300px]]
+| [[File:HAYW_10717_10sec_RotD50_log.png|thumb|300px]]
+|}
+==== Comparisons with Study 18.8 ====
+Study 18.8 curves are in red, and new curves are in black.
+{|
+! Site !! 2 sec !! 3 sec !! 5 sec !! 10 sec !! Vertical profile
+|-
+! s3240
+| [[File:s3240_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3240_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:s3240_RC2_vert_profile.png|thumb|250px]]
+|-
+! ALBY
+| [[File:ALBY_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_RC2_vert_profile.png|thumb|250px]]
+|-
+! SJO
+| [[File:SJO_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SJO_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:SJO_RC2_vert_profile.png|thumb|250px]]
+|-
+! CFCS
+| [[File:CFCS_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_RC2_vert_profile.png|thumb|250px]]
+|-
+! s3171
+| [[File:s3171_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3171_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:s3171_RC2_vert_profile.png|thumb|250px]]
+|-
+! CSUEB
+| [[File:CSUEB_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_RC2_vert_profile.png|thumb|250px]]
+|-
+! CSU1
+| [[File:CSU1_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_RC2_vert_profile.png|thumb|250px]]
+|-
+! SFRH
+| [[File:SFRH_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_RC2_vert_profile.png|thumb|250px]]
+|-
+! LVMR
+| [[File:LVMR_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_RC2_vert_profile.png|thumb|250px]]
+|-
+! HAYW
+| [[File:HAYW_Aug9_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_Aug9_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_Aug9_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_Aug9_248_v_188_10sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_RC2_vert_profile.png|thumb|250px]]
+|-
+|}
+==== High-frequency curves ====
+{|
+! Site !! 1 sec !! 0.5 sec !! 0.2 sec !! 0.1 sec !! Vertical profile
+|-
+! s3240
+| [[File:s3240_10724_1sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10724_0.5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10724_0.2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_10724_0.1sec_RotD50.png|thumb|300px]]
+| [[File:s3240_vert_profile.png|thumb|250px]]
+|-
+! ALBY
+| [[File:ALBY_10725_1sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10725_0.5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10725_0.2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_10725_0.1sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_vert_profile.png|thumb|250px]]
+|-
+! SJO
+| [[File:SJO_10723_1sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10723_0.5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10723_0.2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_10723_0.1sec_RotD50.png|thumb|300px]]
+| [[File:SJO_vert_profile.png|thumb|250px]]
+|-
+! CFCS
+| [[File:CFCS_10718_1sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10718_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10718_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_10718_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_vert_profile.png|thumb|250px]]
+|-
+! s3171
+| [[File:s3171_10719_1sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10719_0.5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10719_0.2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_10719_0.1sec_RotD50.png|thumb|300px]]
+| [[File:s3171_vert_profile.png|thumb|250px]]
+|-
+! CSUEB
+| [[File:CSUEB_10720_1sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10720_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10720_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_10720_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_vert_profile.png|thumb|250px]]
+|-
+! CSU1
+| [[File:CSU1_10721_1sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10721_0.5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10721_0.2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_10721_0.1sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_vert_profile.png|thumb|250px]]
+|-
+! SFRH
+| [[File:SFRH_10722_1sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10722_0.5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10722_0.2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_10722_0.1sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_vert_profile.png|thumb|250px]]
+|-
+! LVMR
+| [[File:LVMR_10726_1sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10726_0.5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10726_0.2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_10726_0.1sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_vert_profile.png|thumb|250px]]
+|-
+! HAYW
+| [[File:HAYW_10727_1sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10727_0.5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10727_0.2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_10727_0.1sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_vert_profile.png|thumb|250px]]
+|}
 == Updates and Enhancements ==
+*Used smaller study region than in Study 18.8.
+*Removed southern San Andreas events, and created a new ERF.
 == Output Data Products ==
+=== File-based data products ===
+We plan to produce the following data products, which will be stored at CARC:
+==== Deterministic ====
+*Seismograms: 3-component seismograms, 10000 timesteps (400 sec, dt=0.04s) each.
+*PSA: We are removing geometric mean PSA calculations from this study.
+*RotD: PGV, and RotD50, RotD100, and the RotD100 azimuth at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1)
+*Vertical response spectra at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
+*Durations: for X and Y components, energy integral, Arias intensity, cumulative absolute velocity (CAV), and for both velocity and acceleration, 5-75%, 5-95%, and 20-80%.  Also, period-dependent acceleration 5-75%, 5-95%, and 20-80% for 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
+==== Broadband ====
+*Seismograms: 3-component seismograms, 40000 timesteps (400 sec, dt=0.01s) each.
+*PSA: We are removing geometric mean PSA calculations from this study.
+*RotD: PGA, PGV, and RotD50, RotD100, and the the RotD100 azimuth at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)
+*Vertical response spectra at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
+*Durations: for X and Y components, energy integral, Arias intensity, cumulative absolute velocity (CAV), and for both velocity and acceleration, 5-75%, 5-95%, and 20-80%.  Also, period-dependent acceleration 5-75%, 5-95%, and 20-80% for 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)
+=== Database data products ===
+We plan to store the following data products in the database on moment-carc:
+==== Deterministic ====
+*RotD50 for 6 periods (10, 7.5, 5, 4, 3, 2).  Note that we are NOT storing RotD100.
+*Duration: acceleration 5-75% and 5-95% for both X and Y
+==== Broadband ====
+*RotD50 for PGA, PGV, and 19 periods (10, 7.5, 5, 4, 3, 2, 1, 0.75, 0.5, 0.4, 0.3, 0.2, 0.1, 0.075, 0.05, 0.04, 0.03, 0.02, 0.01).  Note that we are NOT storing RotD100.
+=== Hazard products ===
+For each site, we will produce hazard curves from the deterministic results at 10, 5, 3, and 2 seconds, and from the broadband results at 10, 5, 3, 2, 1, 0.5, 0.2, and 0.1 seconds.
+When the study is complete, we will produce maps from the deterministic results at 10, 5, 3, and 2 seconds, and from the broadband results at 10, 5, 3, 2, 1, 0.5, 0.2, and 0.1 seconds.
+=== Data products after the study ===
+After the study completes, we plan to compute Fourier spectra for all 3 components:
+*For deterministic, at 27 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1).
+*For broadband at 68 periods (20, 17, 15, 13, 12, 10, 8.5, 7.5, 6.5, 6, 5.5, 5, 4.4, 4, 3.5, 3, 2.8, 2.6, 2.4, 2.2, 2, 1.7, 1.5, 1.3, 1.2, 1.1, 1, 0.85, 0.75, 0.65, 0.6, 0.55, 0.5, 0.45, 0.4, 0.35, 0.3, 0.28, 0.26, 0.24, 0.22, 0.2, 0.17, 0.15, 0.13, 0.12, 0.11, 0.1, 0.085, 0.075, 0.065, 0.06, 0.055, 0.05, 0.045, 0.04, 0.035, 0.032, 0.029, 0.025, 0.022, 0.02, 0.017, 0.015, 0.013, 0.012, 0.011, 0.01)
 == Computational and Data Estimates ==
+=== Computational Estimates ===
+We based these estimates on the test sites.
+{| class="wikitable"
+|+SGT calculation
+! !! UCVM runtime !! UCVM nodes !! SGT runtime (3 components) !! SGT nodes !! Other SGT workflow jobs !! SGT Total
+|-
+! Average of 11 test sites
+| 761 sec || 96 || 7134 sec || 100 || 7200 node-sec || 220 node-hrs
+|}
+node-hrs/site x 315 sites + 10% overrun = 76,230 node-hours for SGT workflows on Frontier.
+{| class="wikitable"
+|+PP calculation
+! !! DirectSynth runtime !! DirectSynth nodes !! Additional runtime for period-dependent calculation !! PP Total
+|-
+! 75th percentile of 10 test sites
+| 13914 sec || 60 || 61938 core-sec || 232.2 node-hrs
+|}
+{| class="wikitable"
+|+BB calculation
+! !! BB runtime !! BB nodes !! Additional runtime for period-dependent calculation !! BB Total
+|-
+! 75th percentile of 10 test sites
+| 8019 sec || 40 || 61938 core-sec || 89.4 node-hrs
+|}
+(232.2+89.7) node-hrs/site x 315 sites + 10% overrun = 111,500 node-hours for PP and BB calculations on Frontera.
+=== Data Estimates ===
+We use the 75th percentile estimate of 206,500 rupture variations.
+We are generating 3-component SGTs and 3-component seismograms, with 10k timesteps (400 sec) for LF and 40k timesteps (400 sec) for BB.
+{| class="wikitable"
+|+Data estimates
+! !! Velocity mesh !! SGTs size !! Temp data !! LF Output data !! BB Output data !! Total output data
+|-
+! Per site, derived from 10 site average (GB)
+| 359 || 1131 || 1490 || 23.7 || 93.6 || 117.3
+|-
+! Total for 335 sites (TB)
+| 110 || 348 || 458 || 7.3 || 28.8 || 36.1
+|}
+==== CARC ====
+We estimate 117.3 GB/site x 315 sites = 36.1 TB in output data, which will be transferred back to CARC.  We currently have 29 TB free.
+==== shock-carc ====
+We estimate (3 MB SGT + 32 MB PP + 219 MB BB logs + 3 MB output products) x 315 sites = 79 GB in workflow log space on /home/shock.  This drive has approximately 1.2 TB free.
+==== moment-carc database ====
+The PeakAmplitudes table uses approximately 183 bytes for data + 179 bytes for index = 363 bytes per entry.
+bytes/entry * 35 entries/event (10 det + 25 stoch) * 206,500 events/site * 315 sites = 768 GB.  The drive on moment-carc with the mysql database has 6.6 TB free.
 == Lessons Learned ==
 == Stress Test ==
+For the stress test, we will run the first 20 sites and check for scientific and technical issues.
+Usage before the stress test:
+*On Frontier, 587,856 of 700,000 node-hours for project GEO156. callag has used 22,166 node-hours.
+*On Frontera, 316,715 of 600,000 node-hours for project EAR20006.  scottcal has used 11,274 node-hours.
+The stress test began on 8/27/24 at 11:25:23 PDT.
+To help us finish the stress test before the SCEC AM, TACC granted us a Frontera reservation for 200 nodes for 8 days, beginning on 8/28/24 at 8 am PDT.  We didn't realized we needed to specify the --reservation tag, so we began utilizing it around 9 am PDT.
+We gave the reservation back in the morning of 8/30.  After the stress test, callag had used 32,660 node-hours on Frontier and scottcal used 18,493 node-hours on Frontera.
+Stress test computational cost:
+*SGTs: 10494/20 sites = 524.7 node-hours per site, about 2.4x what we estimated.  This is mostly due to having used meshes with a -55 degree angle, resulting in larger meshes requiring more computation time.
+*PP and BB: 370.0 node-hours per site, about 15% more than we estimated.
+=== Changes from stress test ===
+Based on the stress test, we made the following changes:
+*Reduced ramp-up time for DirectSynth worker processes.
+*Fixed issue with PGV writing to files in the BB codes.
+*Changed mesh angle from -55 to -36 degrees.
+*Changed smoothing zone from 10 km on either side of the boundary to 20 km.
+*Fixed issue with vertical response and period duration files not automatically transferred.
+*Discovered issue with accessing moment-carc through the USC VPN - confirmed that neither Xiaofeng nor Kevin can access it.
+=== Stress test results ===
+Below are hazard curves for the 20 test sites in the stress test.  A KML file with the stress test sites is available [[Media:Study_24_8_stress_test_sites.kml|here]].
+==== Low-frequency ====
+These curves (in black) include comparisons with Study 18.8 (in red)
+{|
+! Site !! 2 sec !! 3 sec !! 5 sec !! 10 sec
+|-
+! s3240
+| [[File:s3240_r10730_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3240_r10730_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3240_r10730_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3240_r10730_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! ALBY
+| [[File:ALBY_r10731_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_r10731_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_r10731_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:ALBY_r10731_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SJO
+| [[File:SJO_r10732_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! CFCS
+| [[File:CFCS_r10733_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! s3171
+| [[File:s3171_r10734_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3171_r10734_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3171_r10734_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3171_r10734_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! CSUEB
+| [[File:CSUEB_r10735_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_r10735_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_r10735_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CSUEB_r10735_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! CSU1
+| [[File:CSU1_r10736_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_r10736_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_r10736_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CSU1_r10736_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SFRH
+| [[File:SFRH_r10737_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_r10737_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_r10737_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SFRH_r10737_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! LVMR
+| [[File:LVMR_r10738_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_r10738_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_r10738_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:LVMR_r10738_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! HAYW
+| [[File:HAYW_r10739_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_r10739_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_r10739_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:HAYW_r10739_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! s3446
+| [[File:s3446_r10740_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! NAPA
+| [[File:NAPA_r10741_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:NAPA_r10741_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:NAPA_r10741_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:NAPA_r10741_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SRSA
+| [[File:SRSA_r10742_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SRSA_r10742_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SRSA_r10742_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SRSA_r10742_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! MSRA
+| [[File:MSRA_r10743_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:MSRA_r10743_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:MSRA_r10743_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:MSRA_r10743_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! PTRY
+| [[File:PTRY_r10744_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:PTRY_r10744_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:PTRY_r10744_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:PTRY_r10744_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! DALY
+| [[File:DALY_r10745_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:DALY_r10745_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:DALY_r10745_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:DALY_r10745_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SSOL
+| [[File:SSOL_r10746_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SSOL_r10746_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SSOL_r10746_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SSOL_r10746_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! LICK
+| [[File:LICK_r10747_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SSFO
+| [[File:SSFO_r10748_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SSFO_r10748_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SSFO_r10748_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SSFO_r10748_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! BLMT
+| [[File:BLMT_r10749_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+|}
+==== Sites with notable differences ====
+We identified 3 sites with notable differences between Study 24.8 and Study 18.8:
+*LVMR is higher at 10 sec
+*CFCS is higher 2, 3, 5 sec
+*s3171 is lower at 3, 5, 10 sec
+We believe the difference in LVMR is due to the expanded basin added in SFCVM v21.1, and s3171 can be explained by the change in profile as well:
+{|
+! Site !! Profile, SFCVM v21.1 !! Profile, Cencal model used in Study 18.8
+|-
+! LVMR
+| [[File:LVMR_RC2_vert_profile.png|thumb|250px]]
+| [[File:LVMR_cencal_vert_profile.png|thumb|250px]]
+|-
+! s3171
+| [[File:s3171_RC2_vert_profile.png|thumb|250px]]
+| [[File:s3171_cencal_vert_profile.png|thumb|250px]]
+|}
+A scatterplot comparing the average 2 sec RotD50 value for each rupture shows that the Study 24.8 results are consistently higher than the 18.8 results for CFCS:
+{|
+| [[File:CFCS_scatterplot.png|thumb|400px]]
+|}
+We extracted vertical slices for the top from Cencal (floor = 500 m/s) and the Study 24.8 model (taper, floor = 400 m/s) for the top 5000 m along an east-west line running through CFCS.
+{|
+! Vertical slice, Study 24.8 !! Vertical slice, Cencal
+|-
+| [[File:CFCS_RC2_vert_slice.png|thumb|400px]]
+| [[File:CFCS_cencal_vert_slice.png|thumb|400px]]
+|}
+==== Corrected Study 18.8 comparisons ====
+In an attempt to replicate the Study 18.8 results, we discovered that the Study 18.8 velocity models were tiled in a different order than for Study 24.8: CCA-06, then CenCal, then CVM-S4.26.M01, as described [[CyberShake_Study_18.8#Configuration_for_this_study | here]].  Several of the stress test sites fall within the 20 km smoothing zone surrounding the Study 18.8 CCA-06/Cencal interface (interface in blue, 20km zone in white):
+{|
+| [[File:Study_18_8_20km_smoothing_region_stress_test_sites.png|thumb|400px]]
+|}
+We compared the velocity profiles of Study 24.8 and the correct Study 18.8 configuration for the 5 stress test sites.  For CFCS, this explains the sharp increase in hazard.  The Study 18.8 profile is in blue, and the Study 24.8 profile is in orange.
+{|
+! Site !! Vs overlay, top 700m !! 2 sec curve !! 3 sec curve !! 5 sec curve !! 10 sec curve
+|-
+! CFCS
+| [[File:CFCS_248_188_overlay.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:CFCS_r10733_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! SJO
+| [[File:SJO_248_188_overlay.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:SJO_r10732_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! s3446
+| [[File:s3446_248_188_overlay.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:s3446_r10740_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! BLMT
+| [[File:BLMT_248_188_overlay.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:BLMT_r10749_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+! LICK
+| [[File:LICK_248_188_overlay.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_2sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_3sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_5sec_RotD50.png|thumb|300px]]
+| [[File:LICK_r10747_248_v_188_10sec_RotD50.png|thumb|300px]]
+|-
+|}
+==== Impact of rotation angle and smoothing zone ====
+<b>Based on the below analysis, we will rerun the stress test sites with the intended angle of -36 degrees and a 20 km smoothing zone so that all Study 24.8 results will be consistent.</b>
+We discovered that the stress test sites were run with a volume rotation angle of -55 degrees and a smoothing zone width of 10 km on either side of the interface.  This is different from our intended rotation angle of -36 degrees and smoothing zone width of 20 km.  To quantify the impact of this, we ran CFCS with the updated values.  Comparisons are below.  The black curves are the stress test run, the blue curves are the corrected run.
+{|
+! 2 sec !! 3 sec !! 5 sec !! 10 sec
+|-
+| [[File:CFCS_10733_v_10771_2sec_curve.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_3sec_curve.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_5sec_curve.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_10sec_curve.png|thumb|350px]]
+|-
+| [[File:CFCS_10733_v_10771_2sec_scatter.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_3sec_scatter.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_5sec_scatter.png|thumb|350px]]
+| [[File:CFCS_10733_v_10771_10sec_scatter.png|thumb|350px]]
+|}
 == Events During Study ==
+The main study began on 9/24/24 at 11:49:59 PDT.
+We began with a maximum of 5 workflows on Frontier and 20 on Frontera.  Later on 9/24 we increased the number of Frontier workflows to 15.
+On 9/30, moment-carc wasn't passed to the Check Duration job for finishing PP workflows.  I updated the dax generator to correctly pass through the desired database for this job.
+On 9/30, I ran out of /home quota on Frontera.  This was an issue because some of the rvGAHP-related logs are written here, and it resulted in "Failed to start transfer GAHP" errors.  I cleaned up some space on /home and released the jobs.
+On 9/30, the merge_pmc jobs were held because they still included the stress test reservation on Frontera.  I removed the reservation string and released the jobs.
+On 10/1, I found that the cronjob on Frontier to monitor job usage was removed from the crontab, so I added it back.
+On 10/2, I turned off stochastic calculations on Frontera while we investigated the unexpected BB results from the stress test.
+On 10/10, the work2 filesystem on Frontera, where the executables and rupture files are hosted, had a problem, causing all the Frontera jobs to be held.  Additionally, login4, the host which connects to shock, was unavailable.  When login4 returned we restarted the rvGAHP process.
+On 10/16, the scottcal account was added to the CyberShake DesignSafe project.  This meant that scottcal is now part of 3 allocations, leading to a Slurm error when jobs were submitted without specifying an account, meaning Condor jobs were held.  I added the EAR20006 account to all Frontera jobs, and had to manually add it for jobs which were already planned.
+On 10/16, I realized that DirectSynth jobs were requesting a wallclock time of 10 hours, but these jobs are usually only taking a bit more than 4.  I changed the requested job length to 5 hours.
+On 10/17, I discovered that the PP Error jobs were because the corresponding SGT workflow had finished its Update and Handoff jobs, but then the stage-out of the SGTs to Frontera failed because of Globus consents.  The registration job is dependent on stage-out, so it didn't run either.  Then, when the PP workflow tries to plan, it can't find a copy of the SGT files on Frontera and aborts.  I couldn't use the standard CyberShake scripts to restart these workflows, since in the database they were already recorded as SGT Generated, so instead I just reran the pegasus-run commands in the log-plan* files.
+On 10/18, I got an email from TACC staff that the jobs are causing too much load on the scratch filesystem, and a request to reduce the number of simultaneous jobs to 4.  I reduced the number of Frontera slots to 4 in the workflow auto-submission tool, and am following up to learn the specifics of the problem and if there's a way to fix it.
+SGT calculations on Frontier finished on 10/18/24 at 12:59:43 PDT.
+On 10/21, the broadband transfers to Corral for Study 22.12 resulted in going over quota on CARC scratch1 again, interfering with the workflows for this study.  I cleaned up scratch1 and fixed the issue.
+On 10/28-30, the work2 filesystem and scheduler on Frontera had a number of issues, requiring restarts of the rvGAHP daemon and some work to recover the job state.
+=== Renewal of Globus consents ===
+We will track when we renew the Globus consents.
+/6
+/9
+/13
+/17
+/24
+/29
+=== Restarts of the rvgahp daemons ===
+We will track when we restart the rvgahp daemons on login10@frontier and login4@frontera.
+/9 on Frontera
+/10 on Frontera (node crashed)
+/29 on Frontera (filesystem issues)
+/30 on Frontera (continuing filesystem issues)
 == Performance Metrics ==
+At the start of the main study, project geo156 on Frontier has used 609101 node-hours (of 700,000).  User callag has used 33398 node-hours.  Project EAR20006 has used 12925.147 node-hours (of 676,000).  User scottcal has used 503.796 node-hours.
 == Production Checklist ==
+*<s>Run test workflow against moment-carc.</s>
+*<s>Investigate velocity profile differences with Mei's plots (s3171 and HAYW)</s>
+*<s>Wrap period-dependent duration code and test in PP.</s>
+*<s>Wrap period-dependent duration code and test in BB.</s>
+*<s>Integrate period-dependent duration code into workflows.</s>
+*<s>Update data and compute estimates.</s>
+*<s>Determine where to copy output data.</s>
+*<s>Modify workflows to remove double-staging of SGTs to Frontera.</s>
+*<s>Schedule and hold readiness reviews with TACC and OLCF.</s>
+*<s>Modify workflows to only insert RotD50, not RotD100.</s>
+*<s>Science readiness review</s>
+*<s>Technical readiness review</s>
+*<s>Verify that vertical component response is being calculated correctly.</s>
+*<s>Set up cronjobs to monitor usage.</s>
+*<s>Solve issue with putting velocity parameters into the database from Frontier.</s>
+*<s>Tag code in github repository</s>
 == Presentations, Posters, and Papers ==
 == References ==

Difference between revisions of "CyberShake Study 24.8"

Latest revision as of 19:28, 30 October 2024

Contents

Status

Data Products

Science Goals

Technical Goals

Sites

Ruptures to Include

Source Contribution Curves

Disaggregations

s3430

s3446

SJO

Velocity Model

Primary 3D model

Potential modification to gabbro regions

Background model

Cross-sections

Cross-sections, no smoothing, CVM-S4.26.M01 1D background

Cross-sections, smoothing, CVM-S4.26.M01 1D background

Cross-sections, no smoothing, Southern Sierra BBP 1D background

Cross-sections, no smoothing, extended SFCVM Sierra 1D background, CCA + taper

Cross-sections, smoothing, extended SFCVM Sierra 1D background, CCA + taper

Cross-sections, no smoothing, extended SFCVM Sierra 1D background with taper, CCA + taper

Candidate Model (RC1)

Vp/Vs Ratio Adjustment

Candidate Model (RC2)

Strain Green Tensors

Vertical Component

Rupture Generator

High-frequency codes

Hazard Curve Tests

Results using velocity model RC1

Low-frequency curves

High-frequency curves

Results using velocity model RC2

Low-frequency curves

Comparisons with Study 18.8

High-frequency curves

Updates and Enhancements

Output Data Products

File-based data products

Deterministic

Broadband

Database data products

Deterministic

Broadband

Hazard products

Data products after the study

Computational and Data Estimates

Computational Estimates

Data Estimates

CARC

shock-carc

moment-carc database

Lessons Learned

Stress Test

Changes from stress test

Stress test results

Low-frequency

Sites with notable differences

Corrected Study 18.8 comparisons

Impact of rotation angle and smoothing zone

Events During Study

Renewal of Globus consents

Restarts of the rvgahp daemons

Performance Metrics

Production Checklist

Presentations, Posters, and Papers

References

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