# Creates a diffuse layer with a rough dielectric coating
import sys
sys.path.append('.')
import layerlab as ll
albedo = [0.5, 0.5, 0.6]
eta = 1.5
alpha = 0.02 # Beckmann roughness
# Construct quadrature scheme suitable for the material
n, m = ll.parameterHeuristicMicrofacet(eta=eta, alpha=alpha)
mu, w = ll.quad.gaussLobatto(n)
print("# of nodes = %i, fourier orders = %i" % (n, m))
# Construct coating layer
print("Creating coating layer")
coating = ll.Layer(mu, w, m)
coating.setMicrofacet(eta=eta, alpha=alpha)
output = []
for channel in range(3):
# Construct diffuse bottom layer for each channel
print("Creating diffuse layer")
l = ll.Layer(mu, w, m)
l.setDiffuse(albedo[channel])
# Apply coating
print("Applying coating..")
l.addToTop(coating)
# This step integrates the spectral IOR against the CIE XYZ curves to obtain
# equivalent sRGB values. This may seem fairly approximate but turns out to
# yield excellent agreement with spectral reference renders
print('Computing gold IOR parameters')
eta_bot = get_rgb(gold)
alpha_top = 0.1 # Beckmann roughness of top layer (coating)
alpha_bot = 0.1 # Beckmann roughness of bottom layer (gold)
# Medium parameters
g = 0.5 # Scattering anisotropy
albedo = [0.25, 0.0, 0.95] # Single scattering albedo
tau = 0.5 # Optical depth
# Construct quadrature scheme suitable for the material
n_top, m_top = ll.parameterHeuristicMicrofacet(eta=eta_top, alpha=alpha_top)
n_bot, m_bot = ll.parameterHeuristicMicrofacet(eta=eta_bot[0], alpha=alpha_bot)
n_med, m_med = ll.parameterHeuristicHG(g=g)
n = max(n_top, n_bot) # Max of zenith angle discretization
m = m_top # Number of Fourier orders determined by top layer
mu, w = ll.quad.gaussLobatto(n)
print("# of nodes = %i, fourier orders = %i" % (n, m))
# Construct coating layer
print("Creating coating layer")
coating = ll.Layer(mu, w, m)
coating.setMicrofacet(eta=eta_top, alpha=alpha_top)
output = []
for channel in range(3):
import layerlab as ll
eta_top = 1.5
# This step integrates the spectral IOR against the CIE XYZ curves to obtain
# equivalent sRGB values. This may seem fairly approximate but turns out to
# yield excellent agreement with spectral reference renders
print('Computing gold IOR parameters')
eta_bot = get_rgb(gold)
alpha_top = 0.1 # Beckmann roughness of top layer (coating)
alpha_bot = 0.1 # Beckmann roughness of bottom layer (gold)
# Construct quadrature scheme suitable for the material
n_top, m_top = ll.parameterHeuristicMicrofacet(eta=eta_top, alpha=alpha_top)
n_bot, m_bot = ll.parameterHeuristicMicrofacet(eta=eta_bot[0], alpha=alpha_bot)
n = max(n_top, n_bot) # Max of zenith angle discretization
m = m_top # Number of Fourier orders determined by top layer
mu, w = ll.quad.gaussLobatto(n)
print("# of nodes = %i, fourier orders = %i" % (n, m))
# Construct coating layer
print("Creating coating layer")
coating = ll.Layer(mu, w, m)
coating.setMicrofacet(eta=eta_top, alpha=alpha_top)
output = []
for channel in range(3):
# Construct diffuse bottom layer for each channel
print("Creating metal layer")
# Creates a diffuse layer with a rough dielectric coating
import sys
sys.path.append('.')
import layerlab as ll
albedo = [0.5, 0.5, 0.6]
eta = 1.5
alpha = 0.02 # Beckmann roughness
# Construct quadrature scheme suitable for the material
n, m = ll.parameterHeuristicMicrofacet(eta=eta, alpha=alpha)
mu, w = ll.quad.gaussLobatto(n)
print("# of nodes = %i, fourier orders = %i" % (n, m))
# Construct coating layer
print("Creating coating layer")
coating = ll.Layer(mu, w, m)
coating.setMicrofacet(eta=eta, alpha=alpha)
output = []
for channel in range(3):
# Construct diffuse bottom layer for each channel
print("Creating diffuse layer")
l = ll.Layer(mu, w, m)
l.setDiffuse(albedo[channel])
# Apply coating
print("Applying coating..")
l.addToTop(coating)
