###
interps = ["LinLinLog", "LogLogLog", "LinLinLin"]
methods = ["Simplified Union", "One D Union", "Two D Union"]
interps = ["LogLogLog", "LinLinLin"]
methods = ["Two D Union"]
for interp in interps:
print "\n-----", interp, "-----"
for method in methods:
coupled_dist = Collision.createLinLinLogCorrelatedCoupledElasticDistribution(
pb_data, method, 1e-15)
if interp == "LogLogLog":
coupled_dist = Collision.createLogLogLogCorrelatedCoupledElasticDistribution(
pb_data, method, 1e-15)
elif interp == "LinLinLin":
coupled_dist = Collision.createLinLinLinCorrelatedCoupledElasticDistribution(
pb_data, method, 1e-15)
print "\n----- ", method, " -----\n"
print "\t -- evaluateLegendreExpandedRutherford --\n"
etas = [
2.51317958942017e3, 2.68213671998009, 4.14887699806239e-14,
2.51317958942017e3
]
angles = [[0.999999], [1.0, 1.0, 1.0], [0.999999], [1.0]]
energies = [[1.0e-5], [1.0e-4, 5.5e-4, 1.0e-3], [1.0e5], [1.0e-5]]
for i in range(0, len(etas)):
print "Eta = ", etas[i]
for j in range(0, len(angles[i])):
cutoff_pdf = coupled_dist.evaluatePDFAtCutoff(energies[i][j])
pdf = coupled_dist.evaluateScreenedRutherfordPDF(
if interpolation == "LogLogLog":
labels.append(schemes[n] + " - log")
if schemes[n] == "Unit-base":
dist = Collision.createLogLogLogUnitBaseCoupledElasticDistribution(native_data, "One D Union", tol)
if schemes[n] == "Unit-base Correlated":
dist = Collision.createLogLogLogUnitBaseCorrelatedCoupledElasticDistribution(native_data, "Two D Union", tol)
if schemes[n] == "Correlated":
dist = Collision.createLogLogLogCorrelatedCoupledElasticDistribution(native_data, "Two D Union", tol)
elif interpolation == "LinLinLin":
labels.append(schemes[n] + " - lin")
if schemes[n] == "Unit-base":
dist = Collision.createLinLinLinUnitBaseCoupledElasticDistribution(native_data, "Two D Union", tol)
if schemes[n] == "Unit-base Correlated":
dist = Collision.createLinLinLinUnitBaseCorrelatedCoupledElasticDistribution(native_data, "Two D Union", tol)
if schemes[n] == "Correlated":
dist = Collision.createLinLinLinCorrelatedCoupledElasticDistribution(native_data, "Two D Union", tol)
for i in range(0, length):
pdfs[n, i] = dist.evaluatePDF(energy, angles[i])
cdfs[n, i] = dist.evaluateCDF(energy, angles[i])
if schemes[n] == "Unit-base":
labels[n] = "Lower " + schemes[n] + " - log"
upper_samples = numpy.zeros(len(random_numbers))
Num = n
# Sample both upper and lower distrbutions
lower_random_numbers = numpy.zeros((len(random_numbers)*2))
upper_random_numbers = numpy.zeros((len(random_numbers)*2))
lower_random_numbers[0::2] = random_numbers
upper_random_numbers[0::2] = random_numbers
