moble · April 21, 2024 19:52 · moble · Apr 18, 2024 · moble · Apr 21, 2024
diff --git a/evaluate_bondi_norms.py b/evaluate_bondi_norms.py
 #%%
 """
 This script shows how to load CCE data into a `scri.AsymptoticBondiData` object
 and evaluate a set of constraints that should be satisfied involving the strain
 and the Newman-Penrose quantities (assuming the waveform is in Bondi gauge).
 These constraints are listed in the plot legend (see below) as equations to be
 satisfied at each instant.  The violation is just one side minus the other, and
 the norm is that difference squared integrated over the sphere (and
 square-rooted).
 """

 import time
 import numpy as np
 import matplotlib.pyplot as plt
 import scri


 # The data output by SpEC make certain choices for tetrad
 # normalizations, which I assume are shared by SpECTRE
 convention = "SpEC"


 # This is for the current SpECTRE CCE output format
 file_format = "spectrecce1"


 # Absolute or relative path to the file containing the CCE data
 file_name = "/home/fs01/nd357/Runs/GhDgFdPaper/8Points/CceOutputR200.h5"


 # Now we load up the files.  This may take several minutes (probably due to weird chunking)
 t1 = time.perf_counter()
 abd1 = scri.SpEC.file_io.create_abd_from_h5(
    file_format,
    convention=convention,
    file_name=file_name
 )
 t2 = time.perf_counter()
 print(f"Time to load file: {t2-t1} s")


 # The next step will take forever if we don't downsample the data
 abd2 = abd1.interpolate(abd1.time[::50])


 # Now, just compute the norms of the Bondi constraints
 constraint_norms = abd2.bondi_violation_norms

 #%% Plot the results
 plt.semilogy(abd2.t, np.array(constraint_norms).T)
 plt.xlabel("Time (code units)")
 plt.ylabel(r"Bondi-constraint violation $L^2$ norms")
 plt.legend([
    "ψ̇₀ = ðψ₁ + 3 σ ψ₂",
    "ψ̇₁ = ðψ₂ + 2 σ ψ₃",
    "ψ̇₂ = ðψ₃ + 1 σ ψ₄",
    "ψ₃ = -∂ðσ̄/∂u",
    "ψ₄ = -∂²σ̄/∂u²",
    "Im[ψ₂] = -Im[ð²σ̄ + σ ∂σ̄/∂u]"
 ])
 # plt.title("")
 plt.savefig("BondiViolationNorms.png");
 plt.show()
	#%%
	"""
	This script shows how to load CCE data into a `scri.AsymptoticBondiData` object
	and evaluate a set of constraints that should be satisfied involving the strain
	and the Newman-Penrose quantities (assuming the waveform is in Bondi gauge).
	These constraints are listed in the plot legend (see below) as equations to be
	satisfied at each instant. The violation is just one side minus the other, and
	the norm is that difference squared integrated over the sphere (and
	square-rooted).
	"""

	import time
	import numpy as np
	import matplotlib.pyplot as plt
	import scri


	# The data output by SpEC make certain choices for tetrad
	# normalizations, which I assume are shared by SpECTRE
	convention = "SpEC"


	# This is for the current SpECTRE CCE output format
	file_format = "spectrecce1"


	# Absolute or relative path to the file containing the CCE data
	file_name = "/home/fs01/nd357/Runs/GhDgFdPaper/8Points/CceOutputR200.h5"


	# Now we load up the files. This may take several minutes (probably due to weird chunking)
	t1 = time.perf_counter()
	abd1 = scri.SpEC.file_io.create_abd_from_h5(
	file_format,
	convention=convention,
	file_name=file_name
	)
	t2 = time.perf_counter()
	print(f"Time to load file: {t2-t1} s")


	# The next step will take forever if we don't downsample the data
	abd2 = abd1.interpolate(abd1.time[::50])


	# Now, just compute the norms of the Bondi constraints
	constraint_norms = abd2.bondi_violation_norms

	#%% Plot the results
	plt.semilogy(abd2.t, np.array(constraint_norms).T)
	plt.xlabel("Time (code units)")
	plt.ylabel(r"Bondi-constraint violation $L^2$ norms")
	plt.legend([
	"ψ̇₀ = ðψ₁ + 3 σ ψ₂",
	"ψ̇₁ = ðψ₂ + 2 σ ψ₃",
	"ψ̇₂ = ðψ₃ + 1 σ ψ₄",
	"ψ₃ = -∂ðσ̄/∂u",
	"ψ₄ = -∂²σ̄/∂u²",
	"Im[ψ₂] = -Im[ð²σ̄ + σ ∂σ̄/∂u]"
	])
	# plt.title("")
	plt.savefig("BondiViolationNorms.png");
	plt.show()