def __init__(self, Conf_Folder, LinesLogHeader_Name): #Import the library with the fitting algorithms with gaussians Fitting_Gaussians.__init__(self) LineMesurer_Log.__init__(self, Conf_Folder, LinesLogHeader_Name) #Line definition self.Current_Label = None self.Current_Ion = None self.Current_TheoLoc = None #Textfile where we store our data self.Current_LinesLog = None #Vector we use to store the 6 wavelengths which define the emision line location and the two continuums self.Selections = [] #Indexes for the "Selections vector" wavelengths self.ind1 = None #Wave1 self.ind2 = None #Wave2 self.ind3 = None #Wave3 self.ind4 = None #Wave4 self.ind5 = None #Wave5 self.ind6 = None #Wave6 #New design self.BoxSize = 70 #Dictionary to store the data self.Parameter_dict = OrderedDict.fromkeys(self.ColumnHeaderVector) #Extra mechanisms for testing the wide component on Halpha self.force_WD = True
def __init__(self, Conf_Folder, LinesLogHeader_Name): #Import the library with the fitting algorithms with gaussians Fitting_Gaussians.__init__(self) LineMesurer_Log.__init__(self, Conf_Folder, LinesLogHeader_Name) #Line definition self.Current_Label = None self.Current_Ion = None self.Current_TheoLoc = None #Textfile where we store our data self.Current_LinesLog = None #Without a graphical interface we need a dataframe with the possible blended lines self.blendedLines_Table() #New design self.BoxSize = 70 #Dictionary to store the data self.Parameter_dict = OrderedDict.fromkeys(self.ColumnHeaderVector) #Extra mechanisms for testing the wide component on Halpha self.force_WD = True #Parameters to save in log #WARNING: Missing emission line type self.saving_parameters_list = ['Ion', 'lambda_theo', 'lambda_obs', 'flux_intg', 'flux_intg_er', 'flux_gauss', 'flux_gauss_er', 'eqw', 'eqw_er', 'A', 'A_er', 'mu', 'mu_er', 'sigma', 'sigma_er', 'zerolev_mean', #continuum linear value at line region center 'zerolev_std', 'zerolev_width', 'm_zerolev', 'n_zerolev', 'Wave1', 'Wave2', 'Wave3', 'Wave4', 'Wave5', 'Wave6', 'blended_check', 'line_number', 'group_label', 'add_wide_component', 'fit_routine']
def __init__(self, Conf_Folder, LinesLogHeader_Name): #Import the library with the fitting algorithms with gaussians Fitting_Gaussians.__init__(self) LineMesurer_Log.__init__(self, Conf_Folder, LinesLogHeader_Name) #Line definition self.Current_Label = None self.Current_Ion = None self.Current_TheoLoc = None #Textfile where we store our data self.Current_LinesLog = None #Estimated parameters for Gaussian [A, mu, sigma] self.p_0 = None #Predicted parameters for Gaussian [A, mu, sigma] self.p_1 = None #Standard deviations for parameters for Gaussian std[A, mu, sigma] only in MCMC methods self.p_1_stdev = None #Mean value and deviation for the Gaussian from MCMC self.p_1_Area_Norm = None #Line equivalent width self.EqW = None #Line parameters from direct integration and classic error self.Flux_Brute = None self.SigmaF = None self.SigmaEW = None #Line parameters from gaussian fitting self.Flux_Gauss = None self.SigmaF_MCMC = None self.SigmaEW_MCMC = None #Continuum dispersion self.SigmaContinuum = None #Fitted continuum properties self.Continuum_Gradient = None #Assuming a line this is the gradient (m) self.Continuum_n = None #Assuming a line this is the y axis interception point (n) self.ContinuumWidth = None #Number of pixels used in the continuum fitting in both the blue and red regions self.LocalMedian = None #Fitted continuum value at the peaks wavelength self.ContinuumFlux = None #Vector with the fitted continuum values in the line region #Boolean parameters self.EmissionType = None #True Emission line, False absorption #Deblending self.List_BlendedLines = self.BlendedLines_Table() self.ProceedToDeblend = False self.Num = None #1 if current line is in the location we are currently measuring self.Current_BlendedGroup = None #The group of blended lines we are considering self.Deblend_Check = None #Blended: Line cannot be divided into components. Deblended: Line has been divided into components self.Lower_Wav_Measured = False #Check for making sure we are only going to measure a line blended if it has the lowest wavelength self.Current_Blended_Label = None #Vector we use to store the 6 wavelengths which define the emision line location and the two continuums self.Selections = [] #Indexes for the "Selections vector" wavelengths self.ind1 = None #Wave1 self.ind2 = None #Wave2 self.ind3 = None #Wave3 self.ind4 = None #Wave4 self.ind5 = None #Wave5 self.ind6 = None #Wave6 #New design self.BoxSize = 70