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Merge pull request #14 from astriffling/master
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NCPA class improvement
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cheritier authored Jan 15, 2024
2 parents e998701 + 104942d commit b39b1c2
Showing 1 changed file with 81 additions and 25 deletions.
106 changes: 81 additions & 25 deletions OOPAO/NCPA.py
Original file line number Diff line number Diff line change
Expand Up @@ -2,32 +2,37 @@
"""
Created on Sat Dec 3 13:22:10 2022
@author: cheritier
@author: cheritier -- astriffl
"""
import numpy as np
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% CLASS INITIALIZATION %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
class NCPA:

def __init__(self,telescope, zernike_coefficients = None):
def __init__(self, tel, dm, atm, modal_basis='KL', coefficients = None, f2=None, seed=5):
"""
************************** REQUIRED PARAMETERS **************************
An NCPA object consists in defining the 2D map that acts as a static OPD offset. It requires the following parameters
_ telescope : the telescope object that contains all the informations (diameter, pupil, etc)
_ tel : the telescope object that contains all the informations (diameter, pupil, etc)
_ dm : the deformable mirror object that contains all the informations (nAct, misregistrations, etc)
_ atm : the atmosphere object that contains all the informations (layers, r0, windspeed, etc)
************************** OPTIONAL PARAMETERS **************************
_ zernike_coefficients : a list of coefficients of Zernike Polynomials (see Zernike class). The coefficients are normalized to 1 m.
_ modal_basis : str, 'KL' (default) or 'Zernike' as modal basis for NCPA generation
_ coefficients : a list of coefficients of chosen modal basis. The coefficients are normalized to 1 m.
_ f2 : a list of 3 elements [amplitude, start mode, end mode, cutoff_freq] which will follow 1/f2 law
_ seed : pseudo-random value to create the NCPA with repeatability
************************** MAIN PROPERTIES **************************
The main properties of a Telescope object are listed here:
_ NCPA.OPD : the optical path difference
The main properties of a NCPA object are listed here:
_ NCPA.OPD : the optical path difference map
************************** EXEMPLE **************************
1) Create a blank NCPA object corresponding to a Telescope object
ncpa = NCPA(telescope = tel)
ncpa = NCPA(tel,dm,atm)
2) Update the OPD of the NCPA object using a given OPD_map
ncpa.OPD = OPD_map
Expand All @@ -36,25 +41,76 @@ def __init__(self,telescope, zernike_coefficients = None):
src = Source(optBand = 'H', magnitude = 8)
src*tel
3) Create an NCPA object corresponding based on a linear combinaison of Zernike coefficients
3) Create an NCPA object corresponding based on a linear combinaison of modal coefficients(Zernike or KL)
list_coefficients = [0,0,10e-9,20e-9]
ncpa = NCPA(telescope = tel, zernike_coefficients = list_coefficients)
ncpa = NCPA(tel,dm,atm,coefficients = list_coefficients) --> NCPA based on KL modes
ncpa = NCPA(tel,dm,atm,modal_basis='Zernike',coefficients = list_coefficients) --> NCPA based on Zernikes modes
4) Create an NCPA following an 1/f2 distribution law on modes amplitudes
ncpa = NCPA(tel,dm,atm,f2=[200e-9,5,25,1]) --> 200 nm RMS NCPA as an 1/f2 law of modes 5 to 25 with a cutoff frequency of 1
"""
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% INITIALIZATION %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
self.isInitialized = False # Resolution of the telescope
if zernike_coefficients is None:
self.OPD = self.pupil.astype(float)
# %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% INITIALIZATION %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
self.basis = modal_basis
self.tel = tel
self.atm = atm
self.dm = dm
self.seed = seed

if f2 is None:
if coefficients is None:
self.OPD = self.pupil.astype(float)

if coefficients is not None:
if type(coefficients) is list:
if self.basis=='KL':
self.B = self.KL_basis()[:,:,:len(coefficients)]

if self.basis=='Zernike':
n_max = len(coefficients)
self.B = self.Zernike_basis(n_max)
else:
raise TypeError('The zernike coefficients should be input as a list.')

self.OPD = np.matmul(self.B,np.asarray(coefficients))

else:
if type(zernike_coefficients) is list:
n_max = len(zernike_coefficients)
from OOPAO.Zernike import Zernike
self.Z = Zernike(telescope,J=n_max)
self.Z.computeZernike(telescope)

else:
raise TypeError('The zernike coefficients should be input as a list.')

self.NCPA_f2_law(f2)

self.tag = 'NCPA'
self.NCPA_properties()

def NCPA_f2_law(self,f2):
if type(f2) is list and len(f2)==4:
if self.basis=='KL':
self.B = self.KL_basis()
phase = np.sum([np.random.RandomState(i*self.seed).randn()/np.sqrt(i+f2[3])*self.B[:,:,i] for i in range(f2[1],f2[2])],axis=0)
self.OPD = phase / np.std(phase[np.where(self.tel.pupil==1)]) * f2[0]

self.OPD = np.matmul(self.Z.modesFullRes,np.asarray(zernike_coefficients))
self.tag = 'NCPA'
if self.basis=='Zernike':
self.B = self.Zernike_basis(f2[2])
self.OPD = np.sum([np.random.RandomState(i*self.seed).randn()/np.sqrt(i+f2[3])*self.B[:,:,i] for i in range(f2[1],f2[2])],axis=0)
self.OPD = self.OPD / np.std(self.OPD[np.where(self.tel.pupil==1)]) * f2[0]
else:
raise TypeError('f2 should be a list containing [amplitude, start_mode, end_mode, cutoff]')

def KL_basis(self):
from OOPAO.calibration.compute_KL_modal_basis import compute_KL_basis
M2C_KL = compute_KL_basis(self.tel, self.atm, self.dm,lim=1e-2)
self.dm.coefs = M2C_KL
self.tel*self.dm
B = self.tel.OPD
return B

def Zernike_basis(self,n_max):
from OOPAO.Zernike import Zernike
self.Z = Zernike(self.tel,J=n_max)
self.Z.computeZernike(self.tel)
B = self.Z.modesFullRes
return B

def NCPA_properties(self):
print()
print('------------ NCPA ------------')
print('{:^20s}|{:^9s}'.format('Modal basis',self.basis))
print('{:^20s}|{:^9.2f}'.format('Amplitude [nm RMS]',np.std(self.OPD[np.where(self.tel.pupil>0)])*1e9))
print('------------------------------')

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