%matplotlib inline
import os
from functools import partial
from pathlib import Path
import h5py
import matplotlib.pyplot as plt
import numpy as np
import salvus.namespace as sn
import salvus.toolbox.toolbox as st
SALVUS_FLOW_SITE_NAME = os.environ.get("SITE_NAME", "local")
ranks = 2
mesh = sn.simple_mesh.basic_mesh.CartesianHomogeneousAcoustic2D(
vp=1000.0, rho=1000.0, x_max=1.0, y_max=1.0, max_frequency=12500.0
).create_mesh()
mesh.elemental_fields.clear()
mesh_order_1 = mesh.copy()
mesh_order_1.change_tensor_order(1)
mesh_order_4 = mesh.copy()
mesh_order_4.change_tensor_order(4)
axis = np.random.choice([0, 1])
coords_order_1 = mesh_order_1.get_element_nodes()[:, :, axis].flatten()
coords_order_4 = mesh_order_4.get_element_nodes()[:, :, axis].flatten()
def li(x: np.ndarray, min_val, max_val) -> np.ndarray:
"""Linearly interpolate a parameter over a coordinate array.
Parameters
----------
x : np.ndarray
Flattened coordinate array (either x or y).
min_val : float
Value of the parameter at the minimum coordinate.
max_val : float
Value of the parameter at the maximum coordinate.
Returns
-------
np.ndarray
An array of values linearly interpolated over the coordinate range.
"""
m = (max_val - min_val) / (np.max(x) - np.min(x))
return m * x + min_val
vp0, vp1 = 1000, 2000
rho = 1000
m10 = m11 = 1 / rho
m00 = m10 / vp0**2
m01 = m11 / vp1**2
m0 = (np.apply_along_axis(li, 0, coords_order_1, m00, m01)).reshape(
mesh_order_1.nelem, mesh_order_1.nodes_per_element
) * 0.5
m1 = (np.apply_along_axis(li, 0, coords_order_1, m10, m11)).reshape(
mesh_order_1.nelem, mesh_order_1.nodes_per_element
) * 0.5
mesh_order_1.attach_field("M0", m0)
mesh_order_1.attach_field("M1", m1)
mesh_order_1.attach_field("fluid", np.ones(mesh.nelem))
mesh_order_1
<salvus.mesh.data_structures.unstructured_mesh.unstructured_mesh.UnstructuredMesh object at 0x7f6782828590>
m0 = (np.apply_along_axis(li, 0, coords_order_4, m00, m01)).reshape(
mesh_order_4.nelem, mesh_order_4.nodes_per_element
) * 0.5
m1 = (np.apply_along_axis(li, 0, coords_order_4, m10, m11)).reshape(
mesh_order_4.nelem, mesh_order_4.nodes_per_element
) * 0.5
mesh_order_4.attach_field("M0", m0)
mesh_order_4.attach_field("M1", m1)
mesh_order_4.attach_field("fluid", np.ones(mesh.nelem))
mesh_order_4
<salvus.mesh.data_structures.unstructured_mesh.unstructured_mesh.UnstructuredMesh object at 0x7f683f62b590>
# Source in the left borehole.
src = sn.simple_config.source.cartesian.ScalarPoint2D(
x=0.1,
y=0.5,
f=1,
source_time_function=sn.simple_config.stf.Ricker(center_frequency=1e4),
)
# String of receivers in the right borehole.
recs = sn.simple_config.receiver.cartesian.SideSetVerticalPointCollection2D(
y=np.linspace(0, 1, 101),
side_set_name="x1",
station_code="xx",
fields=["phi"],
offset=-0.1,
)
w1 = sn.simple_config.simulation.Waveform(
mesh=mesh_order_1, sources=src, receivers=recs
)
# Output receivers in simplified HDF5 format.
w1.output.point_data.format = "hdf5"
# Run the simulation long enough that wave hit the receivers.
w1.physics.wave_equation.end_time_in_seconds = 1e-3
# Output the state variable at all time steps (for comparison).
w1.output.volume_data.format = "hdf5"
w1.output.volume_data.fields = ["phi"]
w1.output.volume_data.filename = "output.h5"
w1.output.volume_data.sampling_interval_in_time_steps = 1
# Validate and plot.
w1.validate()
w1
<salvus.flow.simple_config.simulation.waveform.Waveform object at 0x7f67712bd050>
# Output folder 1.
of1 = Path("output_order_1")
# Run.
sn.api.run(
ranks=ranks,
get_all=True,
input_file=w1,
overwrite=True,
site_name=SALVUS_FLOW_SITE_NAME,
output_folder=of1,
)
SalvusJob `job_2407050953017528_15a4844cf8` running on `local` with 2 rank(s). Site information: * Salvus version: 2024.1.1 * Floating point size: 32 -> Current Task: Time loop complete* Downloaded 43.9 MB of results to `output_order_1`. * Total run time: 1.32 seconds. * Pure simulation time: 1.00 seconds.
<salvus.flow.executors.salvus_job.SalvusJob at 0x7f6770dc6ed0>
ed = sn.EventData.from_output_folder(of1)
ed.plot(receiver_field="phi", component="A")
# Get output data into notebook.
f, ax = plt.subplots(1, 2, figsize=(15, 5))
tri, d1_vol = st.visualize_wavefield_2d(of1 / "output.h5", field="phi")
d1, t, extent = st.get_shotgather(of1 / "receivers.h5", field="phi", axis=1)
# Plot shotgather.
ax[0].imshow(d1, extent=extent, aspect="auto")
ax[0].set_xlabel("Position (m)")
ax[0].set_ylabel("Time (s)")
ax[0].set_title("Shotgather")
# Plot last time step of wavefield.
ax[1].tricontourf(tri, d1_vol[-1, :])
ax[1].set_xlabel("Position (m)")
ax[1].set_ylabel("Position (m)")
ax[1].set_title("Wavefield snapshot")
Text(0.5, 1.0, 'Wavefield snapshot')
w4 = sn.simple_config.simulation.Waveform(
mesh=mesh_order_4, sources=src, receivers=recs
)
w4.output.point_data.format = "hdf5"
w4.physics.wave_equation.end_time_in_seconds = 1e-3
w4.output.volume_data.format = "hdf5"
w4.output.volume_data.fields = ["phi"]
w4.output.volume_data.filename = "output.h5"
w4.output.volume_data.sampling_interval_in_time_steps = 1
w4.validate()
# Output folder 4.
of4 = Path("output_order_4")
# Run.
sn.api.run(
input_file=w4,
site_name=SALVUS_FLOW_SITE_NAME,
ranks=ranks,
output_folder=of4,
overwrite=True,
get_all=True,
)
SalvusJob `job_2407050953033408_866025dfc0` running on `local` with 2 rank(s). Site information: * Salvus version: 2024.1.1 * Floating point size: 32 -> Current Task: Time loop complete* Downloaded 43.9 MB of results to `output_order_4`. * Total run time: 1.10 seconds. * Pure simulation time: 0.91 seconds.
<salvus.flow.executors.salvus_job.SalvusJob at 0x7f6770a10b50>
f = plt.figure(figsize=(15, 10))
gs = f.add_gridspec(2, 2)
ax0 = f.add_subplot(gs[0, 0])
ax1 = f.add_subplot(gs[0, 1])
ax2 = f.add_subplot(gs[1, :])
d1, dt, extent = st.get_shotgather(of1 / "receivers.h5", field="phi", axis=1)
d4, dt, extent = st.get_shotgather(of4 / "receivers.h5", field="phi", axis=1)
ax0.imshow(d1, extent=extent, aspect="auto")
ax0.set_xlabel("Position (m)")
ax0.set_ylabel("Time (s)")
ax0.set_title("Shotgather (order 1)")
ax1.imshow(d4, extent=extent, aspect="auto")
ax1.set_xlabel("Position (m)")
ax1.set_ylabel("Time (s)")
ax1.set_title("Shotgather (order 4)")
ax2.set_title("Trace comparison")
ax2.plot(np.arange(d4.shape[0]) * dt, d1[:, 50], label="Order 1")
ax2.plot(np.arange(d4.shape[0]) * dt, d4[:, 50], label="Order 4", ls="dashed")
ax2.set_xlabel("Time (s)")
ax2.set_ylabel("Amplitude")
ax2.legend()
<matplotlib.legend.Legend at 0x7f6770912e50>
# Testing, removed for tutorial.
np.testing.assert_allclose(d1, d4, atol=1e-5 * np.max(np.abs(d1)))
mesh = sn.simple_mesh.basic_mesh.CartesianHomogeneousAcoustic3D(
vp=1000.0,
rho=1000.0,
x_max=1.0,
y_max=1.0,
z_max=1.0,
max_frequency=5000.0,
).create_mesh()
mesh.elemental_fields.clear()
# Copy into two different meshes and tensorize.
mesh_order_1 = mesh.copy()
mesh_order_1.change_tensor_order(1)
mesh_order_4 = mesh.copy()
mesh_order_4.change_tensor_order(4)
# Choose an axis to interpolate over.
axis = np.random.choice([0, 1, 2])
coords_order_1 = mesh_order_1.get_element_nodes()[:, :, axis].flatten()
coords_order_4 = mesh_order_4.get_element_nodes()[:, :, axis].flatten()
# Interpolate the models (order 1).
m0 = (np.apply_along_axis(li, 0, coords_order_1, m00, m01)).reshape(
mesh_order_1.nelem, mesh_order_1.nodes_per_element
) * 0.5
m1 = (np.apply_along_axis(li, 0, coords_order_1, m10, m11)).reshape(
mesh_order_1.nelem, mesh_order_1.nodes_per_element
) * 0.5
mesh_order_1.attach_field("M0", m0)
mesh_order_1.attach_field("M1", m1)
mesh_order_1.attach_field("fluid", np.ones(mesh.nelem))
mesh_order_1
<salvus.mesh.data_structures.unstructured_mesh.unstructured_mesh.UnstructuredMesh object at 0x7f6770a95790>
# Interpolate the models (order 4).
m0 = (np.apply_along_axis(li, 0, coords_order_4, m00, m01)).reshape(
mesh_order_4.nelem, mesh_order_4.nodes_per_element
) * 0.5
m1 = (np.apply_along_axis(li, 0, coords_order_4, m10, m11)).reshape(
mesh_order_4.nelem, mesh_order_4.nodes_per_element
) * 0.5
mesh_order_4.attach_field("M0", m0)
mesh_order_4.attach_field("M1", m1)
mesh_order_4.attach_field("fluid", np.ones(mesh.nelem))
mesh_order_4
<salvus.mesh.data_structures.unstructured_mesh.unstructured_mesh.UnstructuredMesh object at 0x7f6771170a50>
# Set up a simulation.
# Source in the left borehole.
src = sn.simple_config.source.cartesian.ScalarPoint3D(
x=0.1,
y=0.5,
z=0.5,
f=1,
source_time_function=sn.simple_config.stf.Ricker(center_frequency=5e3),
)
# String of receivers in the right borehole.
recs = [
sn.simple_config.receiver.cartesian.Point3D(
x=0.9, y=0.5, z=z, station_code=f"{i:03d}", fields=["phi"]
)
for i, z in enumerate(np.linspace(0, 1, 101))
]
w1 = sn.simple_config.simulation.Waveform(
mesh=mesh_order_1, sources=src, receivers=recs
)
# Finalize simulation setup.
# Output receivers in simplified HDF5 format.
w1.output.point_data.format = "hdf5"
# Run the simulation long enough that wave hit the receivers.
w1.physics.wave_equation.end_time_in_seconds = 2e-3
# Output the state variable at all time steps (for comparison).
w1.output.volume_data.format = "hdf5"
w1.output.volume_data.fields = ["phi"]
w1.output.volume_data.filename = "output.h5"
w1.output.volume_data.sampling_interval_in_time_steps = 1
# Validate and plot.
w1.validate()
w1
<salvus.flow.simple_config.simulation.waveform.Waveform object at 0x7f67b1f2b7d0>
# Run simulation.
of1 = Path("output_order_1")
# Run.
sn.api.run(
ranks=ranks,
get_all=True,
input_file=w1,
overwrite=True,
site_name=SALVUS_FLOW_SITE_NAME,
output_folder=of1,
)
SalvusJob `job_2407050953510265_35f92f359c` running on `local` with 2 rank(s). Site information: * Salvus version: 2024.1.1 * Floating point size: 32
* Downloaded 286.3 MB of results to `output_order_1`. * Total run time: 2.10 seconds. * Pure simulation time: 1.62 seconds.
<salvus.flow.executors.salvus_job.SalvusJob at 0x7f6770ecfd50>
# Visualize shotgather.
f, ax = plt.subplots(1, 1, figsize=(15, 5))
d1, t, extent = st.get_shotgather(of1 / "receivers.h5", field="phi", axis=2)
# Plot shotgather.
ax.imshow(d1, extent=extent, aspect="auto")
ax.set_xlabel("Position (m)")
ax.set_ylabel("Time (s)")
ax.set_title("Shotgather")
Text(0.5, 1.0, 'Shotgather')
# Do the same for order 4.
w4 = sn.simple_config.simulation.Waveform(
mesh=mesh_order_4, sources=src, receivers=recs
)
w4.output.point_data.format = "hdf5"
w4.physics.wave_equation.end_time_in_seconds = 2e-3
w4.output.volume_data.format = "hdf5"
w4.output.volume_data.fields = ["phi"]
w4.output.volume_data.filename = "output.h5"
w4.output.volume_data.sampling_interval_in_time_steps = 1
w4.validate()
# Output folder 4.
of4 = Path("output_order_4")
# Run.
sn.api.run(
input_file=w4,
site_name=SALVUS_FLOW_SITE_NAME,
ranks=ranks,
output_folder=of4,
overwrite=True,
get_all=True,
)
SalvusJob `job_2407050953871295_5c08eec44f` running on `local` with 2 rank(s). Site information: * Salvus version: 2024.1.1 * Floating point size: 32
* Downloaded 286.3 MB of results to `output_order_4`. * Total run time: 2.67 seconds. * Pure simulation time: 2.19 seconds.
<salvus.flow.executors.salvus_job.SalvusJob at 0x7f676e6e9390>
# Plot and compare results.
f = plt.figure(figsize=(15, 10))
gs = f.add_gridspec(2, 2)
ax0 = f.add_subplot(gs[0, 0])
ax1 = f.add_subplot(gs[0, 1])
ax2 = f.add_subplot(gs[1, :])
d1, dt, extent = st.get_shotgather(of1 / "receivers.h5", field="phi", axis=2)
d4, dt, extent = st.get_shotgather(of4 / "receivers.h5", field="phi", axis=2)
ax0.imshow(d1, extent=extent, aspect="auto")
ax0.set_xlabel("Position (m)")
ax0.set_ylabel("Time (s)")
ax0.set_title("Shotgather (order 1)")
ax1.imshow(d4, extent=extent, aspect="auto")
ax1.set_xlabel("Position (m)")
ax1.set_ylabel("Position (m)")
ax1.set_title("Shotgather (order 4)")
ax2.set_title("Trace comparison")
ax2.plot(np.arange(d1.shape[0]) * dt, d1[:, 50], label="Order 1")
ax2.plot(np.arange(d4.shape[0]) * dt, d4[:, 50], label="Order 4", ls="dashed")
ax2.set_xlabel("Time (s)")
ax2.set_ylabel("Amplitude")
ax2.legend()
<matplotlib.legend.Legend at 0x7f676e6753d0>