Example 06 - Python
Last update: 17.07.2025Python
import clr, os, winreg
from itertools import islice
import matplotlib.pyplot as plt
import numpy as np
class PythonStandaloneApplication(object):
class LicenseException(Exception):
pass
class ConnectionException(Exception):
pass
class InitializationException(Exception):
pass
class SystemNotPresentException(Exception):
pass
def __init__(self, path=None):
# determine location of ZOSAPI_NetHelper.dll & add as reference
aKey = winreg.OpenKey(winreg.ConnectRegistry(None, winreg.HKEY_CURRENT_USER), r"Software\Zemax", 0, winreg.KEY_READ)
zemaxData = winreg.QueryValueEx(aKey, 'ZemaxRoot')
NetHelper = os.path.join(os.sep, zemaxData[0], r'ZOS-API\Libraries\ZOSAPI_NetHelper.dll')
winreg.CloseKey(aKey)
clr.AddReference(NetHelper)
import ZOSAPI_NetHelper
# Find the installed version of OpticStudio
if path is None:
isInitialized = ZOSAPI_NetHelper.ZOSAPI_Initializer.Initialize()
else:
# Note -- uncomment the following line to use a custom initialization path
isInitialized = ZOSAPI_NetHelper.ZOSAPI_Initializer.Initialize(path)
# determine the ZOS root directory
if isInitialized:
dir = ZOSAPI_NetHelper.ZOSAPI_Initializer.GetZemaxDirectory()
else:
raise PythonStandaloneApplication.InitializationException("Unable to locate Zemax OpticStudio. Try using a hard-coded path.")
# add ZOS-API referencecs
clr.AddReference(os.path.join(os.sep, dir, "ZOSAPI.dll"))
clr.AddReference(os.path.join(os.sep, dir, "ZOSAPI_Interfaces.dll"))
import ZOSAPI
# create a reference to the API namespace
self.ZOSAPI = ZOSAPI
# create a reference to the API namespace
self.ZOSAPI = ZOSAPI
# Create the initial connection class
self.TheConnection = ZOSAPI.ZOSAPI_Connection()
if self.TheConnection is None:
raise PythonStandaloneApplication.ConnectionException("Unable to initialize .NET connection to ZOSAPI")
self.TheApplication = self.TheConnection.CreateNewApplication()
if self.TheApplication is None:
raise PythonStandaloneApplication.InitializationException("Unable to acquire ZOSAPI application")
if self.TheApplication.IsValidLicenseForAPI == False:
raise PythonStandaloneApplication.LicenseException("License is not valid for ZOSAPI use")
self.TheSystem = self.TheApplication.PrimarySystem
if self.TheSystem is None:
raise PythonStandaloneApplication.SystemNotPresentException("Unable to acquire Primary system")
def __del__(self):
if self.TheApplication is not None:
self.TheApplication.CloseApplication()
self.TheApplication = None
self.TheConnection = None
def OpenFile(self, filepath, saveIfNeeded):
if self.TheSystem is None:
raise PythonStandaloneApplication.SystemNotPresentException("Unable to acquire Primary system")
self.TheSystem.LoadFile(filepath, saveIfNeeded)
def CloseFile(self, save):
if self.TheSystem is None:
raise PythonStandaloneApplication.SystemNotPresentException("Unable to acquire Primary system")
self.TheSystem.Close(save)
def SamplesDir(self):
if self.TheApplication is None:
raise PythonStandaloneApplication.InitializationException("Unable to acquire ZOSAPI application")
return self.TheApplication.SamplesDir
def ExampleConstants(self):
if self.TheApplication.LicenseStatus == self.ZOSAPI.LicenseStatusType.PremiumEdition:
return "Premium"
elif self.TheApplication.LicenseStatus == self.ZOSAPI.LicenseStatusTypeProfessionalEdition:
return "Professional"
elif self.TheApplication.LicenseStatus == self.ZOSAPI.LicenseStatusTypeStandardEdition:
return "Standard"
else:
return "Invalid"
def reshape(self, data, x, y, transpose = False):
"""Converts a System.Double[,] to a 2D list for plotting or post processing
Parameters
----------
data : System.Double[,] data directly from ZOS-API
x : x width of new 2D list [use var.GetLength(0) for dimension]
y : y width of new 2D list [use var.GetLength(1) for dimension]
transpose : transposes data; needed for some multi-dimensional line series data
Returns
-------
res : 2D list; can be directly used with Matplotlib or converted to
a numpy array using numpy.asarray(res)
"""
if type(data) is not list:
data = list(data)
var_lst = [y] * x;
it = iter(data)
res = [list(islice(it, i)) for i in var_lst]
if transpose:
return self.transpose(res);
return res
def transpose(self, data):
"""Transposes a 2D list (Python3.x or greater).
Useful for converting mutli-dimensional line series (i.e. FFT PSF)
Parameters
----------
data : Python native list (if using System.Data[,] object reshape first)
Returns
-------
res : transposed 2D list
"""
if type(data) is not list:
data = list(data)
return list(map(list, zip(*data)))
if __name__ == '__main__':
zos = PythonStandaloneApplication()
# load local variables
ZOSAPI = zos.ZOSAPI
TheApplication = zos.TheApplication
TheSystem = zos.TheSystem
# creates a new API directory
if not os.path.exists(TheApplication.SamplesDir + "\\API\\Python"):
os.makedirs(TheApplication.SamplesDir + "\\API\\Python")
#! [e06s01_py]
# Create new non-sequential file
TheSystem = TheApplication.CreateNewSystem(ZOSAPI.SystemType.NonSequential)
TheNCE = TheSystem.NCE
#! [e06s01_py]
#! [e06s02_py]
# inserts objects and changes type
TheNCE.InsertNewObjectAt(2)
o1 = TheNCE.GetObjectAt(1)
o2 = TheNCE.GetObjectAt(2)
o1.ChangeType(o1.GetObjectTypeSettings(ZOSAPI.Editors.NCE.ObjectType.SourcePoint))
o2.ChangeType(o2.GetObjectTypeSettings(ZOSAPI.Editors.NCE.ObjectType.DetectorRectangle))
#! [e06s02_py]
#! [e06s03_py]
# modify object's cell values in the NCE
o1.ObjectData.NumberOfAnalysisRays = 1e6
o1.ObjectData.NumberOfLayoutRays = 10
o1.ObjectData.ConeAngle = 2.5
o2.ZPosition = 1
o2.ObjectData.XHalfWidth = 0.1
o2.ObjectData.YHalfWidth = 0.1
o2.ObjectData.NumberXPixels = 100
o2.ObjectData.NumberYPixels = 100
#! [e06s03_py]
#! [e06s04_py]
# Setup and run the ray trace
NSCRayTrace = TheSystem.Tools.OpenNSCRayTrace()
NSCRayTrace.SplitNSCRays = False
NSCRayTrace.ScatterNSCRays = True
NSCRayTrace.UsePolarization = False
NSCRayTrace.IgnoreErrors = True
NSCRayTrace.SaveRays = False
NSCRayTrace.ClearDetectors(0)
NSCRayTrace.RunAndWaitForCompletion()
NSCRayTrace.Close()
#! [e06s04_py]
plt.rcParams["figure.figsize"] = (12, 4)
plt.set_cmap('jet')
plt.subplot(1, 2, 1)
det = 2
#! [e06s05_py]
# extracts the irradiance data from detector
rawData = TheSystem.NCE.GetAllDetectorDataSafe(det, 1)
data = zos.reshape(rawData, rawData.GetLength(0), rawData.GetLength(1))
#data = (np.asarray(tuple(rawData))).reshape(rawData.GetLength(0), rawData.GetLength(1));
irradiance = np.flipud(data);
plt.imshow(irradiance)
#! [e06s05_py]
# irradiance plot formatting
plt.colorbar()
plt.title('Incoherent Irradiance')
plt.xticks([])
plt.yticks([])
plt.subplot(1, 2, 2)
#! [e06s06_py]
# Calculates phase data from Er & Ei
rawData = TheSystem.NCE.GetAllCoherentDataSafe(det, ZOSAPI.Editors.NCE.DetectorDataType.Real);
real = zos.reshape(rawData, rawData.GetLength(0), rawData.GetLength(1))
#real = (np.asarray(tuple(rawData))).reshape(rawData.GetLength(0), rawData.GetLength(1));
rawData = TheSystem.NCE.GetAllCoherentDataSafe(det, ZOSAPI.Editors.NCE.DetectorDataType.Imaginary);
imag = zos.reshape(rawData, rawData.GetLength(0), rawData.GetLength(1))
#imag = (np.asarray(tuple(rawData))).reshape(rawData.GetLength(0), rawData.GetLength(1));
phase = np.flipud(np.arctan2(imag, real) * 180 / np.pi)
plt.imshow(phase)
#! [e06s06_py]
# phase plot formatting
plt.colorbar()
plt.title('Phase')
plt.xticks([])
plt.yticks([])
TheSystem.SaveAs(TheApplication.SamplesDir + '\\API\\Python\\e06_nsc_phase.zos')
# This will clean up the connection to OpticStudio.
# Note that it closes down the server instance of OpticStudio, so you for maximum performance do not do
# this until you need to.
del zos
zos = None
# place plt.show() after clean up to release OpticStudio from memory
plt.show()
Definition: ZemaxService.cs:198
