valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(pRays) # Emission spectrum em = Property.Property(value=ex_em_import.getEm(), propID=PropertyID.PID_EmissionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(em) # Excitation spectrum ex = Property.Property(value=ex_em_import.getEx(), propID=PropertyID.PID_ExcitationSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(ex) # Absorption spectrum aabs = Property.Property(value=ex_em_import.getAbs(), propID=PropertyID.PID_AsorptionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(aabs)
def xsim(z, *params): #create the apps: mieApp = MMPMie('localhost') tracerApp = MMPRaytracer('localhost') comsolApp = MMPComsolDummy('localhost') # Point data conversion to false. Speeds up testing tracerApp._convertPointData = False # Set default LED json tracerApp.setDefaultInputFile('./DefaultLED3.json') #Set refractive indexes to mieApp: pri = Property.Property(1.83, PropertyID.PID_RefractiveIndex, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) mieApp.setProperty(pri) # same for particle_type_2 pri2 = Property.Property(1.84, PropertyID.PID_RefractiveIndex, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) mieApp.setProperty(pri2) hmri = Property.Property(1.55, PropertyID.PID_RefractiveIndex, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) mieApp.setProperty(hmri) #set also another particle type to MieApp: pScat2 = Property.Property(0, PropertyID.PID_ScatteringCrossSections, valueType=ValueType.Vector, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) pPhase2 = Property.Property(0, propID=PropertyID.PID_InverseCumulativeDist, valueType=ValueType.Vector, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) mieApp.setProperty(pScat2) mieApp.setProperty(pPhase2) # Connect fields fTemp = comsolApp.getField(FieldID.FID_Temperature, 0) fHeat = comsolApp.getField(FieldID.FID_Thermal_absorption_volume, 0) tracerApp.setField(fTemp) tracerApp.setField(fHeat) #set the constant properties from *params: p_max = 35.0 p_min = 1.0 p_num = 50 w_max = 1100.0 w_min = 100.0 w_num = 1001 # Particle density dens_p = 5.0 # g/cm3 # Silicone density dens_host = 1.1 # g/cm3 # log mean in microns mu1 = 2.4849 # log standard deviation in microns sigma1 = 0.3878 mu2 = 2.35137 sigma2 = 0.627218 mu = [mu1, mu2] sigma = [sigma1, sigma2] mup = Property.Property(value=mu1, propID=PropertyID.PID_ParticleMu, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) sigmap = Property.Property(value=sigma1, propID=PropertyID.PID_ParticleSigma, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) mup2 = Property.Property(value=mu2, propID=PropertyID.PID_ParticleMu, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) sigmap2 = Property.Property(value=sigma2, propID=PropertyID.PID_ParticleSigma, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) mieApp.setProperty(mup) mieApp.setProperty(sigmap) mieApp.setProperty(mup2) mieApp.setProperty(sigmap2) # Particles diameters in micrometers d = np.linspace(p_min, p_max, p_num) #pdf = lognorm(sigma, scale=np.exp(mu)) #set the changing properties from z: # Weight fractions weight_frac = z / 100.0 print("z, weight_frac = ", z, weight_frac) #run the simulation: # Number of rays to trace pRays = Property.Property(value=1000000, propID=PropertyID.PID_NumberOfRays, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(pRays) n_particles = Property.Property(value=2, propID=PropertyID.PID_NumberOfFluorescentParticles, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(n_particles) #Phosphor efficiencies: p_eff1 = Property.Property(value=0.8, propID=PropertyID.PID_PhosphorEfficiency, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(p_eff1) p_eff2 = Property.Property(value=0.7, propID=PropertyID.PID_PhosphorEfficiency, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) tracerApp.setProperty(p_eff2) # Emission spectrum em = Property.Property(value=ex_em_import.getEm(), propID=PropertyID.PID_EmissionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(em) # Excitation spectrum ex = Property.Property(value=ex_em_import.getEx(), propID=PropertyID.PID_ExcitationSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(ex) # Absorption spectrum aabs = Property.Property(value=ex_em_import.getAbs(), propID=PropertyID.PID_AsorptionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(aabs) # Emission spectrum 2 em2 = Property.Property(value=ex_em_import.getEmRed(), propID=PropertyID.PID_EmissionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) tracerApp.setProperty(em2) # Excitation spectrum 2 ex2 = Property.Property(value=ex_em_import.getExRed(), propID=PropertyID.PID_ExcitationSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) tracerApp.setProperty(ex2) # Absorption spectrum 2 aabs2 = Property.Property(value=ex_em_import.getAbsRed(), propID=PropertyID.PID_AsorptionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_2) tracerApp.setProperty(aabs2) # Solve Mie mieApp.solveStep(0) # Connect functions pScat = mieApp.getProperty(PropertyID.PID_ScatteringCrossSections, 0, objectID=objID.OBJ_PARTICLE_TYPE_1) pPhase = mieApp.getProperty(PropertyID.PID_InverseCumulativeDist, 0, objectID=objID.OBJ_PARTICLE_TYPE_1) pS2 = mieApp.getProperty(PropertyID.PID_ScatteringCrossSections, 0.0, objectID=objID.OBJ_PARTICLE_TYPE_2) pP2 = mieApp.getProperty(PropertyID.PID_InverseCumulativeDist, 0.0, objectID=objID.OBJ_PARTICLE_TYPE_2) tracerApp.setProperty(pScat) tracerApp.setProperty(pPhase) tracerApp.setProperty(pS2) tracerApp.setProperty(pP2) particles_in_um3 = [] j=0 for w_frac in weight_frac: particles_in_um3.extend([st.particlesInVolumeLogNormWeightTotal(w_frac, dens_p, dens_host, mu[j], sigma[j], particle_diameters=d)]) j = j+1 # Particle density #NOTE: If more than 1 particle type, use ValueType.Vector ! vDens = particles_in_um3 pDens = Property.Property(value=vDens, propID=PropertyID.PID_ParticleNumberDensity, valueType=ValueType.Vector, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(pDens) # Solve tracerApp.solveStep(0, runInBackground=False) #get the simulation result value and return it: p = tracerApp.getProperty(PropertyID.PID_LEDCCT, 0, objectID=objID.OBJ_LED) print('CCT: %f' % p.getValue()) p = tracerApp.getProperty(PropertyID.PID_LEDRadiantPower, 0, objectID=objID.OBJ_LED) print('RadiantPower: %f' % p.getValue()) p = tracerApp.getProperty(PropertyID.PID_LEDColor_x, 0, objectID=objID.OBJ_LED) print('Color x: %f' % p.getValue()) p = tracerApp.getProperty(PropertyID.PID_LEDColor_y, 0, objectID=objID.OBJ_LED) print('Color y: %f' % p.getValue()) p = tracerApp.getProperty(PropertyID.PID_LEDSpectrum, 0, objectID=objID.OBJ_LED) print(p.getValue()['wavelengths'][0:10]) print(p.getValue()['intensities'][0:10]) #return CCT: p = tracerApp.getProperty(PropertyID.PID_LEDCCT, 0, objectID=objID.OBJ_LED) return (p.getValue())
def xsim(z, *params): #create the apps: mieApp = MMPMie('localhost') tracerApp = MMPRaytracer('localhost') comsolApp = MMPComsolDummy('localhost') # Point data conversion to false. Speeds up testing tracerApp._convertPointData = False # Set default LED json tracerApp.setDefaultInputFile('./DefaultLED.json') # Connect functions pScat = mieApp.getProperty(PropertyID.PID_ScatteringCrossSections, 0, objectID=objID.OBJ_PARTICLE_TYPE_1) pPhase = mieApp.getProperty(PropertyID.PID_InverseCumulativeDist, 0, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(pScat) tracerApp.setProperty(pPhase) # Connect fields fTemp = comsolApp.getField(FieldID.FID_Temperature, 0) fHeat = comsolApp.getField(FieldID.FID_Thermal_absorption_volume, 0) tracerApp.setField(fTemp) tracerApp.setField(fHeat) #set the constant properties from *params: p_max = 35.0 p_min = 3.0 p_num = 50 w_max = 1100.0 w_min = 100.0 w_num = 1000 # Weight fractions #weight_frac = np.array([24]) / 100.0 #CHANGING PARAMETER!See below # Particle density dens_p = 5.0 # g/cm3 # Silicone density dens_host = 1.1 # g/cm3 # log mean in microns mu = 2.4849 # log standard deviation in microns sigma = 0.3878 # Particles diameters in micrometers d = np.linspace(p_min, p_max, p_num) pdf = lognorm(sigma, scale=np.exp(mu)) #set the changing properties from z: # Weight fractions weight_frac = np.array([z]) / 100.0 print("z, weight_frac = ", z, weight_frac) #run the simulation: # Number of rays to trace pRays = Property.Property(value=100000, propID=PropertyID.PID_NumberOfRays, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(pRays) # Emission spectrum em = Property.Property(value=ex_em_import.getEm(), propID=PropertyID.PID_EmissionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(em) # Excitation spectrum ex = Property.Property(value=ex_em_import.getEx(), propID=PropertyID.PID_ExcitationSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(ex) # Absorption spectrum aabs = Property.Property(value=ex_em_import.getAbs(), propID=PropertyID.PID_AsorptionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1) tracerApp.setProperty(aabs) #logger.info('Properties set!') # Solve Mie mieApp.solveStep(0) for w_frac in weight_frac: particles_in_um3 =\ st.particlesInVolumeLogNormWeightTotal(w_frac, dens_p, dens_host, mu, sigma, particle_diameters=d) # Particle density vDens = particles_in_um3 pDens = Property.Property(value=vDens, propID=PropertyID.PID_ParticleNumberDensity, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_CONE) tracerApp.setProperty(pDens) # Solve tracerApp.solveStep(0, runInBackground=False) #get the simulation result value and return it: p = tracerApp.getProperty(PropertyID.PID_LEDCCT, 0, objectID=objID.OBJ_LED) print('CCT: %f' % p.value) p = tracerApp.getProperty(PropertyID.PID_LEDRadiantPower, 0, objectID=objID.OBJ_LED) print('RadiantPower: %f' % p.value) p = tracerApp.getProperty(PropertyID.PID_LEDColor_x, 0, objectID=objID.OBJ_LED) print('Color x: %f' % p.value) p = tracerApp.getProperty(PropertyID.PID_LEDColor_y, 0, objectID=objID.OBJ_LED) print('Color y: %f' % p.value) p = tracerApp.getProperty(PropertyID.PID_LEDSpectrum, 0, objectID=objID.OBJ_LED) print(p.value['wavelengths'][0:10]) print(p.value['intensities'][0:10]) #return CCT: p = tracerApp.getProperty(PropertyID.PID_LEDCCT, 0, objectID=objID.OBJ_LED) return (p.value)
# em, ex, abs spectrum for each particle_type 1, 2, ...n # Emission spectrum em = Property.Property( value=ex_em_import.getEm(), propID=PropertyID.PID_EmissionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1, ) tracerApp.setProperty(em) # Excitation spectrum ex = Property.Property( value=ex_em_import.getEx(), propID=PropertyID.PID_ExcitationSpectrum, valueType=ValueType.Scalar, time=0.0, units=None, objectID=objID.OBJ_PARTICLE_TYPE_1, ) tracerApp.setProperty(ex) # Absorption spectrum aabs = Property.Property( value=ex_em_import.getAbs(), propID=PropertyID.PID_AsorptionSpectrum, valueType=ValueType.Scalar, time=0.0, units=None,