2020-04-29 17:08:03 +02:00
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import numpy as np
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import re
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from logging import warning
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import astropy.units as u
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from scipy.interpolate import RegularGridInterpolator
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from scipy.integrate import nquad
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from scipy.optimize import bisect
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2020-04-29 17:10:20 +02:00
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from .IPSF import IPSF
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2020-04-29 17:08:03 +02:00
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2020-04-29 17:10:20 +02:00
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class Zemax(IPSF):
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2020-04-29 17:08:03 +02:00
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"""
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A class for modelling the PSF from a Zemax output file
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"""
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2020-04-29 17:19:54 +02:00
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@u.quantity_input(wl="length", d_aperture="length")
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2020-04-29 17:08:03 +02:00
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def __init__(self, file: str, f_number: float, wl: u.Quantity, d_aperture: u.Quantity):
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"""
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Initialize a new PSF from a Zemax file.
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Parameters
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----------
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file : str
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Path to the Zemax-file. The origin of the coordinate system is in the lower left corner of the matrix
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f_number : float
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The working focal number of the optical system
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wl : Quantity
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The central wavelength which is used for calculating the PSF
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d_aperture : Quantity
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The diameter of the telescope's aperture.
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"""
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# Store parameters
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self.__f_number = f_number
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self.__wl = wl
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self.__d_aperture = d_aperture
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# Read PSF from file
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with open(file, encoding="utf16") as fp:
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self.__psf = np.genfromtxt((x.replace(",", ".") for x in fp), delimiter='\t', skip_header=21)
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# Read header parameters from the file
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with open(file, encoding="utf16") as fp:
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head = [next(fp) for _ in range(21)]
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# Parse shape of the grid and check the read PSF-array
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shape = [int(x) for x in re.findall("[0-9]+", list(filter(re.compile("Image grid size: ").match, head))[0])]
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if shape != list(self.__psf.shape):
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warning("Not all PSF entries read.")
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# Parse and calculate the grid width
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grid_delta = [float(x.replace(",", ".")) for x in
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re.findall("[0-9]+,*[0-9]*", list(filter(re.compile("Data area is ").match, head))[0])]
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unit = re.findall(".+(?=\\.$)", re.sub("Data area is [0-9]+,*[0-9]* by [0-9]+,*[0-9]* ", "",
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list(filter(re.compile("Data area is ").match, head))[0]))[0]
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self.__grid_delta = np.array(grid_delta) / np.array(shape) << u.Unit(unit)
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# Parse the center point of the PSF in the grid
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self.__center_point = [int(x) for x in
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re.findall("[0-9]+", list(filter(re.compile("Center point is: ").match, head))[0])]
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def calcReducedObservationAngle(self, contained_energy: float) -> u.Quantity:
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"""
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Calculate the reduced observation angle in lambda / d_ap for the given contained energy.
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Parameters
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----------
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contained_energy : Union[str, int, float, u.Quantity]
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The percentage of energy to be contained within a circle with the diameter reduced observation angle.
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Returns
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-------
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reduced_observation_angle: Quantity
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The reduced observation angle in lambda / d_ap
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"""
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# Create an linear interpolation function for the PSF and the corresponding grid coordinates
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x_range = np.arange(-(self.__center_point[0] - 1), self.__psf.shape[0] - self.__center_point[0] + 1)
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y_range = np.arange(-(self.__center_point[1] - 1), self.__psf.shape[1] - self.__center_point[1] + 1)
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interp = RegularGridInterpolator((y_range, x_range), np.flip(self.__psf, axis=0))
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# Calculate the maximum possible radius as the smallest distance from the center of the PSF to the borders of
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# the grid.
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r_max = min(self.__center_point[0] - 1, self.__center_point[1] - 1,
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self.__psf.shape[0] - self.__center_point[0], self.__psf.shape[1] - self.__center_point[1])
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# Calculate the overall integral of the PSF
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total = np.sum(self.__psf)
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# Find the radius of the circle containing the given percentage of energy. Therefore, the interpolation
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# function is numerically integrated within the radius. The Integration radius is optimized using bisection.
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try:
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r = bisect(lambda r_c: contained_energy -
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nquad(lambda x, y: interp(np.array([y, x])),
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[lambda y: [-1 * np.sqrt(r_c ** 2 - y ** 2), np.sqrt(r_c ** 2 - y ** 2)],
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[-r_c, r_c]], opts={"epsrel": 1e-1})[0] / total, 0, r_max, xtol=0.1)
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except ValueError:
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r = r_max
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# Calculate the reduced observation angle for the radius of the circle. Therefore, first convert the radius in
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# grid elements to plate size, then calculate the corresponding observation angle and reduce it.
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reduced_observation_angle = r * self.__grid_delta[0] / (self.__f_number * self.__d_aperture) * \
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self.__d_aperture / self.__wl
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return reduced_observation_angle * u.dimensionless_unscaled
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2020-04-29 17:10:20 +02:00
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def mapToGrid(self, grid: np.ndarray) -> np.ndarray:
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"""
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Map the integrated PSF values to a sensor grid.
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Parameters
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----------
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grid : ndarray
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The grid to map the values to. The values will only be mapped onto entries with the value 1.
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Returns
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-------
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grid : ndarray
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The grid with the mapped values.
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"""
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pass
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