예제 #1
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파일: Geometry.py 프로젝트: Gaozmmm/LASDiA
def geometry_correction(Q, I_Q, Qbkg, Ibkg_Q, variables, phi_matrix_flag):
    """Function to calcultate all intensity geometrical corrections.
    
    Parameters
    ----------
    Q               : numpy array
                      momentum transfer (nm^-1)
    I_Q             : numpy array
                      measured scattering intensity
    Qbkg            : numpy array
                      background momentum transfer (nm^-1)
    Ibkg_Q          : numpy array
                      background scattering intensity
    variables       : module
                      input variables setted by the user
    phi_matrix_flag : string
                      flag for the phi matrix calculation:
                      "y": calculate phi matrix and save on file
                      "n": read the phi matrix from file
    
    Returns
    -------
    I_Q             : numpy array
                      corrected measured sample intensity
    Ibkg_Q          : numpy array
                      corrected background intensity
    """

    two_theta = UtilityAnalysis.Qto2theta(Q)

    abs_corr_factor = calcAbsCorrection(variables.abs_length, \
        two_theta, variables.dac_thickness, 0)

    num_point = 1000

    phi_matrix_path = "./phi_matrix_" + variables.molecule

    if phi_matrix_flag.lower() == "y":
        ws1, ws2, r1, r2, d = Utility.read_MCC_file(variables.MCC_path,
                                                    variables.MCC_type)
        thickness_sampling, phi_matrix = calc_phi_matrix(variables.phi_matrix_thickness, \
            two_theta, ws1, ws2, r1, r2, d, num_point)
        np.save(phi_matrix_path, phi_matrix)
    else:
        thickness_sampling = np.linspace(0,
                                         variables.phi_matrix_thickness,
                                         num=num_point)
        phi_matrix = np.load(phi_matrix_path + ".npy")

    T_MCC_sample3, T_MCC_DAC3, T_MCC_ALL3 = calc_T_MCC(0.003, thickness_sampling, \
        phi_matrix, "y")
    T_MCC_sample4, T_MCC_DAC4, T_MCC_ALL4 = calc_T_MCC(0.004, thickness_sampling, \
        phi_matrix, "y")
    T_MCC_corr_factor_bkg = calc_T_DAC_MCC_bkg_corr(T_MCC_DAC4, T_MCC_DAC3)

    I_Q = I_Q / (abs_corr_factor * T_MCC_sample4)
    Ibkg_Q = Ibkg_Q * T_MCC_corr_factor_bkg / (abs_corr_factor * T_MCC_sample4)

    return (I_Q, Ibkg_Q)
예제 #2
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    def plotMiddle(self):
        """Function to plot the graph on the Middle Canvas"""

        self.ui.factorPlot.canvas.ax.cla()
        self.ui.factorPlot.canvas.ax.grid(True)

        self.elementList = Utility.molToElemList(self.molecule)
        self.elementParameters = Utility.read_parameters(
            self.elementList, "./elementParameters.txt")

        if self.ui.formFactorCheck.isChecked():
            # print("test fe check")
            self.Q, self.I_Q, self.Qbkg, self.Ibkg_Q = UtilityAnalysis.check_data_length(
                self.Q, self.I_Q, self.Qbkg, self.Ibkg_Q, self.ui.minQ.value(),
                self.ui.maxQ.value())
            self.fe_Q, self.Ztot = MainFunctions.calc_eeff(
                self.elementList, self.Q, self.elementParameters)

            self.ui.factorPlot.canvas.ax.plot(self.Q,
                                              self.fe_Q,
                                              label=r"$f_e(Q)$")
            self.ui.factorPlot.canvas.ax.legend()
            self.ui.factorPlot.canvas.draw()
        # else:
        #     # print("test unchecked")
        #     self.ui.factorPlot.canvas.ax.lines.pop(0)
        #     self.ui.factorPlot.canvas.draw()

        if self.ui.SQCheck.isChecked():
            S_Q = self.SQ()
            self.ui.factorPlot.canvas.ax.plot(self.Q, S_Q, label=r"$S(Q)$")
            self.ui.factorPlot.canvas.ax.legend()
            self.ui.factorPlot.canvas.draw()

        if self.ui.incohCheck.isChecked():
            self.Iincoh_Q = MainFunctions.calc_Iincoh(self.elementList, self.Q,
                                                      self.elementParameters)

            self.ui.factorPlot.canvas.ax.plot(self.Q,
                                              self.Iincoh_Q,
                                              label=r"$I_{incoh}(Q)$")
            self.ui.factorPlot.canvas.ax.legend()
            self.ui.factorPlot.canvas.draw()

        if self.ui.QiQCheck.isChecked():
            self.Sinf = MainFunctions.calc_Sinf(self.elementList, self.fe_Q,
                                                self.Q, self.Ztot,
                                                self.elementParameters)
            self.i_Q = MainFunctions.calc_iQ(S_Q, self.Sinf)
            # self.r = MainFunctions.calc_r(self.Q)
            Qi_Q = self.Q * self.i_Q

            self.ui.factorPlot.canvas.ax.plot(self.Q, Qi_Q, label=r"$Qi(Q)$")
            self.ui.factorPlot.canvas.ax.legend()
            self.ui.factorPlot.canvas.draw()
예제 #3
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파일: Formalism.py 프로젝트: Gaozmmm/LASDiA
def calc_intraComponentFZ(Q, fe_Q, Ztot, QmaxIntegrate, maxQ, elementList, element, \
    x, y, z, elementParameters, damping_factor, aff_mean_squared):
    """Function to calculate the intra-molecular components.

    Parameters
    ----------
    Q                 : numpy array
                        momentum transfer (nm^-1)
    fe_Q              : numpy array
                        effective electric form factor
    Ztot              : int
                        total Z number
    QmaxIntegrate     : float
                        maximum Q value for the intagrations
    maxQ              : float
                        maximum Q value
    elementList       : dictionary("element": multiplicity)
                        chemical elements of the sample with their multiplicity
                        element      : string
                                       chemical element
                        multiplicity : int
                                       chemical element multiplicity
    element           : string array
                        array with the elements in the xyz_file
    x, y, z           : float array
                        atomic coordinate in the xyz_file (nm)
    elementParameters : dictionary("element": parameters)
                        chemical elements of the sample with their parameters
                        element    : string
                                     chemical element
                        parameters : list
                                     list of the parameters
                                     (Z, a1, b1, a2, b2, a3, b3, a4, b4, c, M, K, L)
    damping_factor    : float
                        damp factor

    Returns
    -------
    r                 : numpy array
                        atomic distance (nm)
    Fintra_r          : numpy array
                        intramolecular contribution of F(r)
    """

    iintra_Q = calc_iintraFZ(Q, QmaxIntegrate, maxQ, elementList, element, x,
                             y, z, elementParameters, aff_mean_squared)
    iintradamp_Q = UtilityAnalysis.calc_iintradamp(iintra_Q, Q, QmaxIntegrate,
                                                   damping_factor)
    r = MainFunctions.calc_r(Q)
    Fintra_r = MainFunctions.calc_Fr(r, Q[Q <= QmaxIntegrate],
                                     iintradamp_Q[Q <= QmaxIntegrate])

    return (r, iintradamp_Q, Fintra_r)
예제 #4
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def S_QCalculation(Q, I_Q, Ibkg_Q, scaleFactor, J_Q, Sinf, fe_Q, Ztot, density,
                   Iincoh_Q, minQ, QmaxIntegrate, maxQ, smoothFactor,
                   dampFactor):
    """Function for the S(Q) calculation.
    """

    Isample_Q = MainFunctions.calc_IsampleQ(I_Q, scaleFactor, Ibkg_Q)
    alpha = MainFunctions.calc_alpha(J_Q[Q <= QmaxIntegrate], Sinf,
                                     Q[Q <= QmaxIntegrate],
                                     Isample_Q[Q <= QmaxIntegrate],
                                     fe_Q[Q <= QmaxIntegrate], Ztot, density)
    Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

    S_Q = MainFunctions.calc_SQ(Icoh_Q, Ztot, fe_Q, Sinf, Q, minQ,
                                QmaxIntegrate, maxQ)
    Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(Q, S_Q, Sinf, smoothFactor,
                                                 minQ, QmaxIntegrate, maxQ)
    SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(Ssmooth_Q, Q, Sinf,
                                                QmaxIntegrate, dampFactor)

    return SsmoothDamp_Q
예제 #5
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    def interpolation(self):
        """Function to interpolate data"""

        self.Q, self.I_Q = UtilityAnalysis.data_interpolation(
            self.orgQ, self.orgI_Q, self.ui.minQ.value(), self.ui.maxQ.value(),
            self.ui.interpolationPoints.value())

        self.Qbkg, self.Ibkg_Q = UtilityAnalysis.data_interpolation(
            self.orgQbkg, self.orgIbkg_Q, self.ui.minQ.value(),
            self.ui.maxQ.value(), self.ui.interpolationPoints.value())

        self.ui.rawDataPlot.canvas.ax.lines.pop(0)
        self.ui.rawDataPlot.canvas.ax.lines.pop(0)

        self.ui.rawDataPlot.canvas.ax.plot(self.Q, self.I_Q, "b", label="Data")
        self.ui.rawDataPlot.canvas.ax.legend()
        self.ui.rawDataPlot.canvas.draw()

        self.ui.rawDataPlot.canvas.ax.plot(self.Qbkg,
                                           self.Ibkg_Q,
                                           "g--",
                                           label="Bkg")
        self.ui.rawDataPlot.canvas.ax.legend()
        self.ui.rawDataPlot.canvas.draw()
예제 #6
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def FitRemoveGofRPeaks(Q, SsmoothDamp_Q, Sinf, QmaxIntegrate, Fintra_r,
    iterations, rmin, density, J_Q, Ztot):
    """Equivalent of Igor function
    """
    
    Qi_Q = Q*MainFunctions.calc_iQ(SsmoothDamp_Q, Sinf)
    r, GR = calc_FFT_QiQ(Q, Qi_Q, QmaxIntegrate)
    
    # _, Fintra_r = UtilityAnalysis.rebinning(rintra, Fintra_r, np.amin(Fintra_r), 
        # np.amax(Fintra_r), len(GR))

    # QiQ1 = np.zeros(len(SsmoothDamp_Q))
    # idx, _ = UtilityAnalysis.find_nearest(Qi_Q, QmaxIntegrate)
    # QiQ1[Q<QmaxIntegrate] = Qi_Q[Q<QmaxIntegrate]
    # QiQ1[0] = 0.0
    QiQ[Q>=QmaxIntegrate] = 0.0
    QiQ[0] = 0.0
    
    # GR1 = GR
    DelG = np.zeros(len(GR))
    Rnn = rmin
    DelG[r<Rnn] = GR[r<Rnn]-(Fintra_r[r<Rnn]-4*np.pi*r[r<Rnn]*density)
    
    GRIdealSmallR = Fintra_r-4*np.pi*r*density
    
    for i in range(iterations):
        Q1, QiQCorr = calc_IFFT_Fr(r, DelG)
        mask = np.where((Q1>0.0) & (Q1<QmaxIntegrate))
        QiQ[mask] = QiQ[mask] - (QiQ[mask] / 
            (Q1[mask] *(Sinf + J_Q[:len(Q1[mask])]/Ztot**2)) + 1) * QiQCorr[mask]
        
        r, GR = calc_FFT_QiQ(Q1, QiQ, QmaxIntegrate)
        
        DelG = np.zeros(len(GR))
        DelG[r<Rnn] = GR[r<Rnn]-GRIdealSmallR[r<Rnn]
        
        _, rmin = UtilityAnalysis.find_nearest(r, 0.95*Rnn)
        Rnn = 0.99*r[np.where(GR==np.amin(GR[r>=rmin]))[0][0]]

    # DTemp = DelG
    # DTemp = DTemp**2
    # chi2 = np.mean(DTemp)
    
    DelG = DelG**2
    chi2 = np.mean(DelG)

    return chi2
예제 #7
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파일: Geometry.py 프로젝트: Gaozmmm/LASDiA
def calc_abs_correction(Q, abs_length, thickness, angle):
    """Function to calculate the absorption correction.
    This function can be used to calculate the absorption correction for the diamond
    or for any other object between the sample and the detector.

    The characteristics for some diamonds can be found here:
    http://www.almax-easylab.com/DiamondSelectionPage.aspx

    Parameters
    ----------
    Q           : numpy array
                  momentum transfer (nm^-1)
    abs_length  : float
                  absorption length (cm), @33keV 1.208cm
    thickness   : float
                  object thickness (cm)
    angle       : float
                  object rotation angle respect the XRay beam (deg)

    Returns
    -------
    corr_factor : numpy array
                  correction factor
    """

    # for now...
    # wavelenght  : float
    #               XRay beam wavelenght (nm), @ESRF ID27 0.03738nm
    # wavelenght = 0.03738 # nm
    # two_theta = Qto2theta(Q) # rad

    two_theta = UtilityAnalysis.Qto2theta(Q)

    mu_l = 1 / abs_length
    angle = np.radians(angle)

    path_lenght = thickness / np.cos(two_theta - angle)

    corr_factor = np.exp(-mu_l * path_lenght)

    # I_Qeff = I_Q / corr_factor

    return corr_factor
예제 #8
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파일: Geometry.py 프로젝트: Gaozmmm/LASDiA
def check_phi_matrix(Q, ws1, ws2, r1, r2, d, phiMatrixCalcFlag, phiMatrixPath):
    """Function to make or read from file the phi matrix.

    Parameters
    ----------
    Q                 : numpy array
                        momentum transfer (nm^-1)
    ws1               : float
                        distance between the slits of first set (cm)
    ws2               : float
                        distance between the slits of second set (cm)
    r1                : float
                        first radius
    r2                : float
                        second radius
    d                 : float
                        dimension of slit
    phiMatrixCalcFlag : string
                        flag for the phi matrix calculation
    phiMatrixPath     : string
                        phi matrix path

    Returns
    -------
    phi_matrix        : 2D numpy array
                        dispersion angle matrix for sample+DAC (rad)                     
    """

    two_theta = UtilityAnalysis.Qto2theta(Q)

    if phiMatrixCalcFlag.lower() == "y":
        phi_matrix = calc_phi_matrix(two_theta, ws1, ws2, r1, r2, d)
        np.save(phiMatrixPath, phi_matrix)
    else:
        phi_matrix = np.load(phiMatrixPath)

    thickness_sampling = np.linspace(0, 0.17, num=1000)
    return (thickness_sampling, phi_matrix)
예제 #9
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def calc_IFFT_Fr(r, F_r):
    """Function to calculate the FFT following the IGOR procedure.
    I do not agree with this procedure, but I follow it to compare my results
    with Igor Pro's ones.
    
    Parameters
    ----------
    r      : numpy array
             atomic distance (nm)
    F_r    : numpy array
             F(r)
    
    Returns
    -------
    Q      : numpy array
             momentum transfer (nm^-1)
    Qi_Q   : numpy array
             Qi(Q)
    """

    NumPoints = 2**math.ceil(math.log(len(F_r)-1)/math.log(2))
    F_r = Utility.resize_zero(F_r, NumPoints)
    Q = np.linspace(0.0, 109, 550)
    DelQ = 2*np.pi/(np.mean(np.diff(r))*NumPoints)
    meanDeltar = np.mean(np.diff(r))
    Q1 = fftpack.fftfreq(r.size, meanDeltar)
    Qi_Q = fftpack.fft(F_r)
    Qi_Q = Qi_Q[np.where(Q1>=0.0)]
    Qi_Q = -np.imag(Qi_Q)*meanDeltar
    Q1 = np.arange(0.0, 0.0+DelQ*len(Qi_Q), DelQ)
    
    idxArray = np.zeros(550, dtype=np.int)
    for i in range(len(Q)):
        idxArray[i], _ = UtilityAnalysis.find_nearest(Q1, Q[i])
    Qi_Q = Qi_Q[idxArray]
    
    return (Q, Qi_Q)
예제 #10
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def calc_FFT_QiQ(Q, Qi_Q, QmaxIntegrate):
    """Function to calculate the FFT following the Igor Pro procedure.
    I do not agree with this procedure, but I follow it to compare my results
    with Igor Pro's ones.
    
    Parameters
    ----------
    Q             : numpy array
                    momentum transfer (nm^-1)
    Qi_Q          : numpy array
                    Q*i(Q)
    
    QmaxIntegrate : float
                    maximum Q value for the integrations
    
    Returns
    -------
    r             : numpy array
                    atomic distance (nm)
    F_r           : numpy array
                    F(r)
    """

    pMax, elem = UtilityAnalysis.find_nearest(Q, QmaxIntegrate)
    NumPoints = 2*2*2**math.ceil(math.log(5*(pMax+1))/math.log(2))
    DelR = 2*np.pi/(np.mean(np.diff(Q))*NumPoints)
    Qi_Q = Utility.resize_zero(Qi_Q[Q<=QmaxIntegrate], NumPoints)
    Qi_Q[pMax+1:] = 0.0
    Q = np.arange(np.amin(Q), np.amin(Q)+np.mean(np.diff(Q))*NumPoints, np.mean(np.diff(Q)))
    r = MainFunctions.calc_r(Q)
    F_r = fftpack.fft(Qi_Q)
    F_r = F_r[np.where(r>=0.0)]
    F_r = -np.imag(F_r)*np.mean(np.diff(Q))*2/np.pi
    r = np.arange(0.0, 0.0+DelR*len(F_r), DelR)
    
    return (r, F_r)
예제 #11
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def OptimizeScaleGofRCorr(Q, I_Q, Ibkg_Q, J_Q, fe_Q, maxQ, minQ,
    QmaxIntegrate, Ztot, density, scaleFactor, Sinf, smoothingFactor, rmin, NumPoints,
    dampingFunction, Fintra_r, iterations, scaleStep):
    """Function for the scale factor optimization.
    """
    
    Flag = 0
    NoPeak = 0
    # scaleStep = 0.05
    scaleStepEnd = 0.00006
    numSample = 23
    scaleFactor = scaleFactor-scaleStep*11
    Qorg = Q
    
    # Loop for the range shifting
    while ((10*scaleStep>scaleStepEnd) and (NoPeak<5) and ((Flag==1) or (scaleFactor+scaleStep*1.1>=0))):
        # print("scale loop")
        scaleArray = make_array_loop(scaleFactor, scaleStep, numSample)
        chi2Array = np.zeros(numSample)
        
        for i in range(len(scaleArray)):
            
            # ------------------Kaplow method for scale--------------------
            Q = Qorg
            Subt = calc_Subt(I_Q, Ibkg_Q, scaleArray[i])
            alpha = calc_alpha(J_Q[Q<=QmaxIntegrate], Sinf, 
                Q[Q<=QmaxIntegrate], Subt[Q<=QmaxIntegrate],
                fe_Q[Q<=QmaxIntegrate], Ztot, density)
            
            S_Q = calc_SQ(Q, Subt, alpha, fe_Q, J_Q, Ztot, Sinf, 
                QmaxIntegrate)
                
            Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(Q, S_Q, Sinf, 
                smoothingFactor, 
                minQ, QmaxIntegrate, maxQ)
            Q, Ssmooth_Q = UtilityAnalysis.rebinning(Q, Ssmooth_Q, 0.0, 
                maxQ, NumPoints)
            SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(Ssmooth_Q, Sinf,
                dampingFunction)
            
            chi2Array[i] = FitRemoveGofRPeaks(Q, SsmoothDamp_Q, Sinf, 
                QmaxIntegrate, Fintra_r, iterations, 
                rmin, density, J_Q, Ztot)
        
        # --------------------Range shifting selection --------------------
        
        if np.amax(chi2Array) > 10**8:
            scaleFactor = scaleArray[np.argmin(chi2Array[0:np.argmax(chi2Array)])] - scaleStep*1.1
        else:
            scaleFactor = scaleArray[np.argmin(chi2Array)] - scaleStep*1.1
        
        nearIdx, nearEl = UtilityAnalysis.find_nearest(scaleArray, scaleFactor)

        if nearIdx == 0:
            print("out1")
            scaleFactor -= scaleStep*10
            scaleStep *= 10
            NoPeak += 1
        if nearIdx >= numSample-2:
            print("out2")
            scaleFactor += scaleStep*10
            scaleStep *= 10
            NoPeak += 1

        scaleStep /= 10
        Flag += 1
        print(Flag)

    # ------------------------chi2 curve fit for scale-------------------------

    xFit, yFit, scaleFactor, chi2Min = chi2Fit(scaleFactor, scaleArray, chi2Array)
    # plt.plot(xFit, yFit)
    # plt.grid(True)
    
    print("final scale factor", scaleFactor)
    # plt.show()
    
    return scaleFactor
예제 #12
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def chi2_minimization(scaleFactor, Q, I_Q, Ibkg_Q, J_Q, fe_Q, Iincoh_Q, Sinf,
                      Ztot, density, Fintra_r, r, minQ, QmaxIntegrate, maxQ,
                      smoothFactor, dampFactor, iteration, rmin):
    """Function to calculate the whole loop for the chi2 minimization.
    """

    scaleStep = 0.05
    densityStep = 0.025
    numSample = 23
    numLoopIteration = 0

    plt.ion()
    figure, ax = plt.subplots()

    while True:
        NoPeak = 0
        while True:
            ax.cla()
            ax.grid(True)
            scaleArray = UtilityAnalysis.make_array_loop(
                scaleFactor, scaleStep, numSample)

            chi2Array = np.zeros(numSample)

            plt.xlabel("Scale")
            ax.relim()
            ax.autoscale_view()
            for i in range(len(scaleArray)):
                chi2Array[
                    i], SsmoothDamp_Q, F_r, Fopt_r = KaplowMethod.Kaplow_method(
                        Q, I_Q, Ibkg_Q, J_Q, fe_Q, Iincoh_Q, Sinf, Ztot,
                        scaleArray[i], density, Fintra_r, r, minQ,
                        QmaxIntegrate, maxQ, smoothFactor, dampFactor,
                        iteration, rmin)

                plt.scatter(scaleArray[i], chi2Array[i])
                figure.canvas.draw()

            if np.amax(chi2Array) > 10**8:
                chi2Array = chi2Array[0:np.amax(chi2Array)]

            scaleFactor = scaleArray[np.argmin(chi2Array)] - scaleStep * 1.1

        ax.cla()
        ax.grid(True)

        density0 = density
        densityArray = UtilityAnalysis.make_array_loop(density, densityStep,
                                                       numSample)
        chi2Array = np.zeros(numSample)

        plt.xlabel("Density")
        ax.relim()
        ax.autoscale_view()
        for i in range(len(densityArray)):
            chi2Array[
                i], SsmoothDamp_Q, F_r, Fopt_r = KaplowMethod.Kaplow_method(
                    Q, I_Q, Ibkg_Q, J_Q, fe_Q, Iincoh_Q, Sinf, Ztot,
                    scaleFactor, densityArray[i], Fintra_r, r, minQ,
                    QmaxIntegrate, maxQ, smoothFactor, dampFactor, iteration,
                    rmin)

            plt.scatter(densityArray[i], chi2Array[i])
            figure.canvas.draw()

        xfit, yfit, density = chi2_fit(densityArray, chi2Array)
        plt.plot(xfit, yfit)
        figure.canvas.draw()

        if np.abs(density - density0) > density0 / 25:
            scaleStep = 0.006
            densityStep = density0 / 10
        elif np.abs(density - density0) > density0 / 75:
            scaleStep = 0.0006
            densityStep = density0 / 100
        else:
            scaleStep = 0.00006
            densityStep = density0 / 1000

        numLoopIteration += 1
        if (np.abs(density - density0) < density0 / 2500
                or numLoopIteration > 30):
            break

    plt.ioff()

    return (density, scaleFactor)
예제 #13
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def OptimizeScale(Q, I_Q, Ibkg_Q, J_Q, Iincoh_Q, fe_Q, minQ, QmaxIntegrate,
                  maxQ, Ztot, density, scaleFactor, Sinf, smoothingFactor,
                  rmin, dampingFunction, Fintra_r, iterations, scaleStep, sth,
                  s0th, mccFlag, thickness_sampling, phi_matrix):
    """Function for the scale factor optimization.

    Q                  : numpy array
                         momentum transfer (nm^-1)
    I_Q                : numpy array
                         measured scattering intensity 
    Ibkg_Q             : numpy array
                         background scattering intensity
    J_Q                : numpy array
                         J(Q)
    Iincoh_Q           : numpy array
                         incoherent scattering intensity
    fe_Q               : numpy array
                         effective electric form factor
    minQ               : float
                         minimum Q value
    QmaxIntegrate      : float
                         maximum Q value for the intagrations
    maxQ               : float
                         maximum Q value
    Ztot               : int
                         total Z number
    density            : float
                         average atomic density
    scaleFactor        : float
                         scale factor
    Sinf               : float
                         value of S(Q) for Q->inf
    smoothingFactor    : float
                         smoothing factor
    rmin               : float
                         r cut-off value (nm)
    dampingFunction    : numpy array
                         damping function
    Fintra_r           : numpy array
                         intramolecular contribution of F(r)
    iterations         : int
                         number of iterations
    scaleStep
    sth
    s0th
    MCC_flag
    """

    numSample = 23

    if mccFlag.lower() == "y":
        T_MCC_sth, T_MCC_corr_factor_bkg = Geometry.MCC_correction(
            sth, s0th, thickness_sampling, phi_matrix)

        # print(thickness_sampling)
        # plt.contour(phi_matrix)
        # plt.show()

        # x = np.linspace(0, len(T_MCC_sth), len(T_MCC_sth), endpoint=True)
        # _, T_MCC_sth = UtilityAnalysis.rebinning(x, T_MCC_sth, np.amin(T_MCC_sth),
        #     np.amax(T_MCC_sth), len(I_Q))

        # plt.plot(T_MCC_sth)
        # plt.show()

        I_Q = I_Q / T_MCC_sth
        Ibkg_Q = Ibkg_Q * T_MCC_corr_factor_bkg / (T_MCC_sth)

    flag = 0
    # Loop for the range shifting
    while 1:
        # print(type(scaleFactor))
        # print(type(scaleStep))
        scaleArray = UtilityAnalysis.makeArrayLoop(scaleFactor, scaleStep)
        chi2Array = np.zeros(numSample)
        flag += 1
        print("iter flag ", flag)

        for i in range(numSample):
            print("sample ", i, scaleArray[i])
            # ------------------Kaplow method for scale--------------------

            Isample_Q = MainFunctions.calc_IsampleQ(I_Q, scaleArray[i], Ibkg_Q)
            alpha = MainFunctions.calc_alpha(J_Q[Q <= QmaxIntegrate], Sinf,
                                             Q[Q <= QmaxIntegrate],
                                             Isample_Q[Q <= QmaxIntegrate],
                                             fe_Q[Q <= QmaxIntegrate], Ztot,
                                             density)
            Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

            S_Q = MainFunctions.calc_SQ(Icoh_Q, Ztot, fe_Q, Sinf, Q, minQ,
                                        QmaxIntegrate, maxQ)

            Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(
                Q, S_Q, Sinf, smoothingFactor, minQ, QmaxIntegrate, maxQ)

            SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(
                Ssmooth_Q, Sinf, dampingFunction)

            i_Q = MainFunctions.calc_iQ(SsmoothDamp_Q, Sinf)

            Qi_Q = Q * i_Q
            r, F_r = MainFunctions.calc_Fr(Q[Q <= QmaxIntegrate],
                                           Qi_Q[Q <= QmaxIntegrate])

            Fopt_r, deltaFopt_r = Optimization.calc_optimize_Fr(
                iterations, F_r, Fintra_r, density, i_Q[Q <= QmaxIntegrate],
                Q[Q <= QmaxIntegrate], Sinf, J_Q[Q <= QmaxIntegrate], r, rmin,
                "n")

            deltaFopt_r[np.where(r >= rmin)] = 0.0  # Igor version
            chi2Array[i] = np.mean(deltaFopt_r**2)  # Igor version
            # Fth_r = Fintra_r - 4*np.pi*r*density
            # plt.plot(r, Fth_r)
            # plt.show()
            # print(Fth_r)
            # print(Fintra_r)
            # chi2Array[i] = simps(deltaFopt_r[np.where((r>0)&(r<rmin))]**2)

        # --------------------Range shifting selection --------------------

        plt.scatter(scaleArray, chi2Array)
        plt.grid(True)
        plt.show()

        maxLimit = 10**5
        if np.amax(chi2Array) >= maxLimit:
            scaleArray = scaleArray[0:np.argmax(chi2Array >= maxLimit)]
            chi2Array = chi2Array[0:np.argmax(chi2Array >= maxLimit)]

        if np.argmin(chi2Array) < 6:
            scaleFactor -= scaleStep * 10
        if np.argmin(chi2Array) > 16:
            scaleFactor += scaleStep * 10

        if (np.argmin(chi2Array) >= 6 and np.argmin(chi2Array) <= 16):
            break
        else:
            continue

    # ------------------------chi2 curve fit for scale-------------------------
    # plt.ioff()

    xFit, yFit, scaleFactor, chi2 = IgorFunctions.chi2Fit(
        scaleFactor, scaleArray, chi2Array)

    print("final scale factor", scaleFactor)

    plt.scatter(scaleArray, chi2Array)
    plt.plot(xFit, yFit)
    plt.grid(True)
    plt.show()

    return scaleFactor
예제 #14
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def Kaplow_method(Q, I_Q, Ibkg_Q, J_Q, fe_Q, Iincoh_Q, Sinf, Ztot, scaleFactor,
                  density, Fintra_r, r, minQ, QmaxIntegrate, maxQ,
                  smoothFactor, dampFactor, iteration, rmin):
    """Function to apply the Kaplow method.

    Parameters
    ----------
    variables     : module
                    input variables setted by the user
    Q             : numpy array
                    momentum transfer (nm^-1)
    I_Q           : numpy array
                    measured scattering intensity
    Ibkg_Q        : numpy array
                    background scattering intensity
    J_Q           : numpy array
                    J(Q)
    fe_Q          : numpy array
                    effective electric form factor
    Iincoh_Q      : numpy array
                    incoherent scattering intensity
    Sinf          : float
                    value of S(Q) for Q->inf
    Ztot          : int
                    total Z number
    scaleFactor   : float
                    scale factor
    density       : float
                    average atomic density
    Fintra_r      : numpy array
                    intramolecular contribution of F(r)
    r             : numpy array
                    atomic distance (nm)

    Returns
    -------
    chi2          : float
                    chi2 value
    SsmoothDamp_Q : numpy array
                    smoothed and damped structure factor
    Fopt_r        : numpy array
                    optimized F(r)
    """

    Isample_Q = MainFunctions.calc_IsampleQ(I_Q, scaleFactor, Ibkg_Q)
    alpha = MainFunctions.calc_alpha(J_Q[Q <= QmaxIntegrate], Sinf,
                                     Q[Q <= QmaxIntegrate],
                                     Isample_Q[Q <= QmaxIntegrate],
                                     fe_Q[Q <= QmaxIntegrate], Ztot, density)
    Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

    S_Q = MainFunctions.calc_SQ(Icoh_Q, Ztot, fe_Q, Sinf, Q, minQ,
                                QmaxIntegrate, maxQ)
    Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(Q, S_Q, Sinf, smoothFactor,
                                                 minQ, QmaxIntegrate, maxQ)
    SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(Ssmooth_Q, Q, Sinf,
                                                QmaxIntegrate, dampFactor)

    i_Q = MainFunctions.calc_iQ(SsmoothDamp_Q, Sinf)
    F_r = MainFunctions.calc_Fr(r, Q[Q <= QmaxIntegrate],
                                i_Q[Q <= QmaxIntegrate])

    Fopt_r, deltaFopt_r = Optimization.calc_optimize_Fr(
        iteration, F_r, Fintra_r, density, i_Q[Q <= QmaxIntegrate],
        Q[Q <= QmaxIntegrate], Sinf, J_Q[Q <= QmaxIntegrate], r, rmin, "n")

    chi2 = simps(deltaFopt_r[r < rmin]**2, r[r < rmin])

    return (chi2, SsmoothDamp_Q, F_r, Fopt_r)
예제 #15
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def Kaplow_methodFZ(numAtoms, variables, Q, I_Q, Ibkg_Q, aff_squared_mean,
                    aff_mean_squared, Iincoh_Q, sf, rho0, Fintra_r, r):
    """Function to apply the Kaplow method with Waseda FZ formalism.

    Parameters
    ----------
    numAtoms  : int
                number of atoms in the molecule
    variables : module
                input variables setted by the user
    Q         : numpy array
                momentum transfer (nm^-1)
    I_Q       : numpy array
                measured scattering intensity
    Ibkg_Q    : numpy array
                background scattering intensity
    aff_squared_mean  : numpy array
                        mean of the squared form factor: <f^2>
    aff_mean_squared : numpy array
                       squared of the mean form factor: <f>^2
    Iincoh_Q : numpy array
               incoherent scattering intensity
    sf       : float
               scale factor
    rho0     : float
               average atomic density
    Fintra_r : numpy array
               intramolecular contribution of F(r)
    r        : numpy array
               atomic distance (nm)

    Returns
    -------
    chi2     : float
               chi2 value
    """

    Isample_Q = MainFunctions.calc_IsampleQ(I_Q, sf, Ibkg_Q)
    alpha = Formalism.calc_alphaFZ(Q, Isample_Q, Iincoh_Q, rho0,
                                   aff_squared_mean, aff_mean_squared)
    Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

    S_Q = Formalism.calc_SFZ_Q(Q, Icoh_Q, aff_squared_mean, aff_mean_squared, variables.minQ, \
        variables.QmaxIntegrate, variables.maxQ)
    S_Qsmoothed = UtilityAnalysis.calc_SQsmoothing(Q, S_Q, 1, variables.smooth_factor, \
        variables.minQ, variables.QmaxIntegrate, variables.maxQ)
    S_QsmoothedDamp = UtilityAnalysis.calc_SQdamp(S_Qsmoothed, Q, 1, \
        variables.QmaxIntegrate, variables.damping_factor)

    i_Q = MainFunctions.calc_iQ(S_QsmoothedDamp, 1)
    F_r = MainFunctions.calc_Fr(r, Q[Q<=variables.QmaxIntegrate], \
        i_Q[Q<=variables.QmaxIntegrate])

    # J_Q = Iincoh_Q/aff_mean_squared

    F_rIt, deltaF_rIt = Formalism.calc_optimize_FrFZ(variables.iteration, F_r, \
        Fintra_r, rho0, i_Q[Q<=variables.QmaxIntegrate], Q[Q<=variables.QmaxIntegrate], \
        Iincoh_Q[Q<=variables.QmaxIntegrate], r, variables.rmin)

    chi2 = simps(deltaF_rIt[r < variables.rmin]**2, r[r < variables.rmin])

    return (chi2, S_QsmoothedDamp, F_rIt)
예제 #16
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    numAtoms, element, x, y, z = Utility.read_xyz_file(path)
    
    Q, I_Q = Utility.read_file(variables.data_file)
    Qbkg, Ibkg_Q  = Utility.read_file(variables.bkg_file)

    #--------------------Preliminary calculation-------------------------------
    
    # Q, I_Q, Qbkg, Ibkg_Q = UtilityAnalysis.check_data_length(Q, I_Q, Qbkg, Ibkg_Q, \
        # variables.minQ, variables.maxQ)
    
    fe_Q, Ztot = MainFunctions.calc_eeff(elementList, Q, elementParameters)
    Iincoh_Q = MainFunctions.calc_Iincoh(elementList, Q, elementParameters)
    J_Q = IgorFunctions.calc_JQ(Iincoh_Q, fe_Q)
    Sinf = MainFunctions.calc_Sinf(elementList, fe_Q, Q, Ztot, elementParameters)
    
    dampingFunction = UtilityAnalysis.calc_dampingFunction(Q, variables.dampingFactor,
        variables.QmaxIntegrate, variables.typeFunction)

    #-------------------Intra-molecular components-----------------------------

    iintra_Q = Optimization.calc_iintra(Q, fe_Q, Ztot, variables.QmaxIntegrate, 
        variables.maxQ, elementList, element, x, y, z, elementParameters)
    iintradamp_Q = UtilityAnalysis.calc_iintradamp(iintra_Q, Q, variables.QmaxIntegrate, 
        dampingFunction)
    rintra, Fintra_r = IgorFunctions.calc_FFT_QiQ(Q, Q*iintradamp_Q, variables.QmaxIntegrate)
    
    _, Fintra_r = UtilityAnalysis.rebinning(rintra, Fintra_r, np.amin(rintra), 
        np.amax(rintra), 8192)
    
    _, dampingFunction = UtilityAnalysis.rebinning(Q, dampingFunction, 0.0, 
        variables.maxQ, variables.NumPoints)
    
예제 #17
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def OptimizeDensityGofRCorr(Q, I_Q, Ibkg_Q, J_Q, fe_Q, maxQ, minQ,
    QmaxIntegrate, Ztot, density, scaleFactor, Sinf, smoothingFactor, rmin, NumPoints,
    dampingFunction, Fintra_r, iterations, densityStep, densityStepEnd):
    """Function for the density optimization.
    """
    
    Flag = 0
    NoPeak = 0
    # densityStep = density/50
    # densityStepEnd = density/250
    numSample = 23
    density = density-densityStep*11
    Qorg = Q
    
    while ((10*densityStep>densityStepEnd) and (NoPeak<5)): # Loop for the range shifting
        densityArray = make_array_loop(density, densityStep, numSample)
        chi2Array = np.zeros(numSample)
        
        for i in range(len(densityArray)):
            
            # ------------------Kaplow method for scale--------------------
            Q = Qorg
            Subt = calc_Subt(I_Q, Ibkg_Q, scaleFactor)
            alpha = calc_alpha(J_Q[Q<=QmaxIntegrate], Sinf, 
                Q[Q<=QmaxIntegrate], Subt[Q<=QmaxIntegrate],
                fe_Q[Q<=QmaxIntegrate], Ztot, densityArray[i])
            
            S_Q = calc_SQ(Q, Subt, alpha, fe_Q, J_Q, Ztot, Sinf, 
                QmaxIntegrate)
                
            Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(Q, S_Q, Sinf, 
                smoothingFactor, 
                minQ, QmaxIntegrate, maxQ)
            Q, Ssmooth_Q = UtilityAnalysis.rebinning(Q, Ssmooth_Q, 0.0, 
                maxQ, NumPoints)
            SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(Ssmooth_Q, Sinf,
                dampingFunction)
            
            chi2Array[i] = FitRemoveGofRPeaks(Q, SsmoothDamp_Q, Sinf, 
                QmaxIntegrate, Fintra_r, iterations, 
                rmin, densityArray[i], J_Q, Ztot)
        
        # --------------------Range shifting selection --------------------

        density = densityArray[np.argmin(chi2Array)] - densityStep*1.1
        
        nearIdx, nearEl = UtilityAnalysis.find_nearest(densityArray, density)
        
        if nearIdx == 0:
            print("out3")
            density -= densityStep*10
            densityStep *= 10
            NoPeak += 1
        if nearIdx >= numSample-2:
            print("out4")
            density += densityStep*10
            densityStep *= 10
            NoPeak += 1

        densityStep /= 10
        
        Flag += 1
        print(Flag)
        plt.scatter(densityArray, chi2Array)
        plt.grid(True)
        # plt.show
        # if ((10*densityStep<=densityStepEnd) and (NoPeak>=5)):
            # break
        
    # ------------------------chi2 curve fit for scale-------------------------
    
    xFit, yFit, density, chi2Min = chi2Fit(density, densityArray, chi2Array)

    print("final density", density)
    return density
예제 #18
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def OptimizeThicknessRef(Q, I_Q, Ibkg_Q, J_Q, Iincoh_Q, fe_Q, maxQ, minQ,
                         QmaxIntegrate, Ztot, density, scaleFactor, sth, s0th,
                         Sinf, smoothingFactor, rmin, dampingFunction,
                         Fintra_r, iterations, s0thStep, ws1, ws2, r1, r2, d,
                         phi_matrix_flag):
    """Function for the thickness optimization.
    """

    Flag = 0
    NoPeak = 0
    s0th = max(s0th - s0thStep * 11, 0.0)
    s0thStepEnd = 0.0006
    numSample = 23

    # Loop for the range shifting
    while 1:
        s0thArray = IgorFunctions.makeArrayLoop(s0th, s0thStep)
        chi2Array = np.zeros(numSample)

        for i in range(numSample):

            # ------------------Kaplow method for scale--------------------

            T_MCC_sth, T_MCC_corr_factor_bkg = Geometry.MCCCorrection(
                sth, s0thArray[i], thickness_sampling, phi_matrix)

            I_Q = I_Q / T_MCC_sth
            Ibkg_Q = Ibkg_Q * T_MCC_corr_factor_bkg / (T_MCC_sth)

            Isample_Q = MainFunctions.calc_IsampleQ(I_Q, scaleFactor, Ibkg_Q)
            alpha = MainFunctions.calc_alpha(J_Q[Q <= QmaxIntegrate], Sinf,
                                             Q[Q <= QmaxIntegrate],
                                             Isample_Q[Q <= QmaxIntegrate],
                                             fe_Q[Q <= QmaxIntegrate], Ztot,
                                             density)
            Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

            S_Q = MainFunctions.calc_SQ(Icoh_Q, Ztot, fe_Q, Sinf, Q, minQ,
                                        QmaxIntegrate, maxQ)

            Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(
                Q, S_Q, Sinf, smoothingFactor, minQ, QmaxIntegrate, maxQ)

            SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(
                Ssmooth_Q, Sinf, dampingFunction)

            i_Q = MainFunctions.calc_iQ(SsmoothDamp_Q, Sinf)

            Qi_Q = Q * i_Q
            r, F_r = MainFunctions.calc_Fr(Q[Q <= QmaxIntegrate],
                                           Qi_Q[Q <= QmaxIntegrate])

            Fopt_r, deltaFopt_r = Optimization.calc_optimize_Fr(
                iterations, F_r, Fintra_r, density, i_Q[Q <= QmaxIntegrate],
                Q[Q <= QmaxIntegrate], Sinf, J_Q[Q <= QmaxIntegrate], r, rmin,
                "n")

            deltaFopt_r[np.where(r >= rmin)] = 0.0
            chi2Array[i] = np.mean(deltaFopt_r**2)

        # --------------------Range shifting selection --------------------

        if np.amax(chi2Array) > 10**8:
            s0thIdx = np.argmin(chi2Array[0:np.argmax(chi2Array)])
        else:
            s0thIdx = np.argmin(chi2Array)

        s0th = s0thArray[s0thIdx] - s0thStep * 1.1
        nearIdx, nearEl = UtilityAnalysis.find_nearest(s0thArray, s0th)

        if nearIdx == 0:
            print("out1")
            s0th -= s0thStep * 10
            s0thStep *= 10
            NoPeak += 1
        if nearIdx >= numSample - 2:
            print("out2")
            s0th += s0thStep * 10
            s0thStep *= 10
            NoPeak += 1

        s0thStep /= 10
        Flag += 1

        if ((10 * s0thStep > s0thStepEnd) and (NoPeak < 5)):
            continue
        else:
            break

    # ------------------------chi2 curve fit for scale-------------------------

    xFit, yFit, sth, chi2 = IgorFunctions.chi2Fit(s0th, s0thArray, chi2Array)

    print("final sample thickness ref", s0th)

    return s0th
예제 #19
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    def SQ(self):
        """Function to calculate and plot the structure factor S(Q)"""

        self.elementList = Utility.molToElemList(self.molecule)
        # self.elementList = Utility.molToElemList("Ar")
        self.elementParameters = Utility.read_parameters(
            self.elementList, "./elementParameters.txt")

        # print(elementList)
        # print(elementParameters)

        self.Q, self.I_Q, self.Qbkg, self.Ibkg_Q = UtilityAnalysis.check_data_length(
            self.Q, self.I_Q, self.Qbkg, self.Ibkg_Q, self.ui.minQ.value(),
            self.ui.maxQ.value())

        two_theta = UtilityAnalysis.Qto2theta(self.Q)
        absCorrFactor = Geometry.calcAbsCorrection(
            self.ui.absLength.value(), two_theta, self.ui.dacThickness.value(),
            self.ui.dacAngle.value())
        self.I_Q = self.I_Q / absCorrFactor
        self.Ibkg_Q = self.Ibkg_Q / absCorrFactor

        self.fe_Q, self.Ztot = MainFunctions.calc_eeff(self.elementList,
                                                       self.Q,
                                                       self.elementParameters)
        self.Iincoh_Q = MainFunctions.calc_Iincoh(self.elementList, self.Q,
                                                  self.elementParameters)
        self.J_Q = MainFunctions.calc_JQ(self.Iincoh_Q, self.Ztot, self.fe_Q)
        self.Sinf = MainFunctions.calc_Sinf(self.elementList, self.fe_Q,
                                            self.Q, self.Ztot,
                                            self.elementParameters)

        self.dampingFunct = UtilityAnalysis.calc_dampingFunction(
            self.Q,
            self.ui.dampingFactor.value(), self.ui.QmaxIntegrate.value(),
            self.ui.dampingFunction.currentText())

        Isample_Q = MainFunctions.calc_IsampleQ(
            self.I_Q, self.ui.scaleFactorValue.value(), self.Ibkg_Q)
        alpha = MainFunctions.calc_alpha(
            self.J_Q[self.Q <= self.ui.QmaxIntegrate.value()], self.Sinf,
            self.Q[self.Q <= self.ui.QmaxIntegrate.value()],
            Isample_Q[self.Q <= self.ui.QmaxIntegrate.value()],
            self.fe_Q[self.Q <= self.ui.QmaxIntegrate.value()], self.Ztot,
            self.ui.densityValue.value())
        Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, self.Iincoh_Q)

        S_Q = MainFunctions.calc_SQ(Icoh_Q, self.Ztot, self.fe_Q, self.Sinf,
                                    self.Q, self.ui.minQ.value(),
                                    self.ui.QmaxIntegrate.value(),
                                    self.ui.maxQ.value())
        Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(
            self.Q, S_Q, self.Sinf, self.ui.smoothingFactor.value(),
            self.ui.minQ.value(), self.ui.QmaxIntegrate.value(),
            self.ui.maxQ.value())
        self.SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(
            Ssmooth_Q, self.Sinf, self.dampingFunct)

        # self.ui.factorPlot.canvas.ax.plot(self.Q, self.SsmoothDamp_Q, "b", label=r"$S(Q)$")
        # self.ui.factorPlot.canvas.ax.legend()
        # self.ui.factorPlot.canvas.draw()

        return self.SsmoothDamp_Q
예제 #20
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    elementList = Utility.molToElemList(inputVariables["molecule"])
    elementParameters = Utility.read_parameters(
        elementList, inputVariables["elementParamsPath"])
    elementPosition = Utility.read_xyz_file(inputVariables["xyzPath"])

    Q, I_Q = Utility.read_file(inputVariables["dataFile"])
    Qbkg, Ibkg_Q = Utility.read_file(inputVariables["bkgFile"])

    # plt.plot(Q, I_Q)
    # plt.plot(Qbkg, Ibkg_Q)
    # plt.show

    #--------------------Preliminary calculation-------------------------------

    Q, I_Q = UtilityAnalysis.data_interpolation(Q, I_Q, inputVariables["minQ"],
                                                inputVariables["maxQ"],
                                                inputVariables["numPoints"])
    Qbkg, Ibkg_Q = UtilityAnalysis.data_interpolation(
        Qbkg, Ibkg_Q, inputVariables["minQ"], inputVariables["maxQ"],
        inputVariables["numPoints"])

    # plt.plot(Q, I_Q)
    # plt.plot(Qbkg, Ibkg_Q)
    # plt.show

    fe_Q, Ztot = MainFunctions.calc_eeff(elementList, Q, elementParameters)
    Iincoh_Q = MainFunctions.calc_Iincoh(elementList, Q, elementParameters)
    J_Q = MainFunctions.calc_JQ(Iincoh_Q, Ztot, fe_Q)
    Sinf = MainFunctions.calc_Sinf(elementList, fe_Q, Q, Ztot,
                                   elementParameters)
    dampingFunction = UtilityAnalysis.calc_dampingFunction(
예제 #21
0
    path = Utility.path_xyz_file(variables.molecule)
    numAtoms, element, x, y, z = Utility.read_xyz_file(path)

    Q, I_Q = Utility.read_file(variables.data_file)
    Qbkg, Ibkg_Q = Utility.read_file(variables.bkg_file)

    # -------------------Preliminary calculation-------------------------------

    fe_Q, Ztot = MainFunctions.calc_eeff(elementList, Q, elementParameters)
    Iincoh_Q = MainFunctions.calc_Iincoh(elementList, Q, elementParameters)
    J_Q = MainFunctions.calc_JQ(Iincoh_Q, Ztot, fe_Q)
    Sinf = MainFunctions.calc_Sinf(elementList, fe_Q, Q, Ztot,
                                   elementParameters)

    dampingFunction = UtilityAnalysis.calc_dampingFunction(
        Q, variables.dampingFactor, variables.QmaxIntegrate,
        variables.typeFunction)

    # ------------------Intra-molecular components-----------------------------

    iintra_Q = Optimization.calc_iintra(Q, fe_Q, Ztot, variables.QmaxIntegrate,
                                        variables.maxQ, elementList, element,
                                        x, y, z, elementParameters)
    iintradamp_Q = UtilityAnalysis.calc_iintradamp(iintra_Q, dampingFunction)
    Qiintradamp_Q = Q * iintradamp_Q
    rintra, Fintra_r = MainFunctions.calc_Fr(
        Q[Q <= variables.QmaxIntegrate],
        Qiintradamp_Q[Q <= variables.QmaxIntegrate])

    # _, Fintra_r = UtilityAnalysis.rebinning(rintra, Fintra_r, np.amin(Fintra_r),
    # np.amax(Fintra_r), 8192)
예제 #22
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    def Optimization(self):
        """Function to optimize and plot F(r)"""

        #-------------------Intra-molecular components-----------------------------

        # numAtoms, element, x, y, z = Utility.read_xyz_file(self.XYZFilePath)
        numAtoms, element, x, y, z = Utility.read_xyz_file(
            "/Users/ciccio/work/ID27/LASDiA/xyzFiles/Ar.xyz")

        iintra_Q = Optimization.calc_iintra(self.Q, self.fe_Q, self.Ztot,
                                            self.ui.QmaxIntegrate.value(),
                                            self.ui.maxQ.value(),
                                            self.elementList, element, x, y, z,
                                            self.elementParameters)
        iintradamp_Q = UtilityAnalysis.calc_iintradamp(iintra_Q,
                                                       self.dampingFunct)
        Qiintradamp_Q = self.Q * iintradamp_Q
        rintra, Fintra_r = MainFunctions.calc_Fr(
            self.Q[self.Q <= self.ui.QmaxIntegrate.value()],
            Qiintradamp_Q[self.Q <= self.ui.QmaxIntegrate.value()])

        scaleFactor = self.ui.scaleFactorValue.value()
        density0 = self.ui.densityValue.value()

        # ----------------------First scale minimization---------------------------

        scaleStep = 0.05

        # sth = 0.008
        # s0th = 0.006
        sth = 0.0
        s0th = 0.0
        phi_matrix = 0.0
        thickness_sampling = 0.0

        scaleFactor = Minimization.OptimizeScale(
            self.Q, self.I_Q, self.Ibkg_Q, self.J_Q, self.Iincoh_Q, self.fe_Q,
            self.ui.maxQ.value(), self.ui.minQ.value(),
            self.ui.QmaxIntegrate.value(), self.Ztot, density0,
            scaleFactor, self.Sinf, self.ui.smoothingFactor.value(),
            self.ui.rmin.value(), self.dampingFunct, Fintra_r,
            self.ui.iterations.value(), scaleStep, sth, s0th,
            thickness_sampling, phi_matrix, "n")

        # ----------------------First density minimization-------------------------

        densityStep = density0 / 50
        densityStepEnd = density0 / 250

        density = Minimization.OptimizeDensity(
            self.Q, self.I_Q, self.Ibkg_Q, self.J_Q, self.Iincoh_Q, self.fe_Q,
            self.ui.maxQ.value(), self.ui.minQ.value(),
            self.ui.QmaxIntegrate.value(), self.Ztot, density0,
            scaleFactor, self.Sinf, self.ui.smoothingFactor.value(),
            self.ui.rmin.value(), self.dampingFunct, Fintra_r,
            self.ui.iterations.value(), densityStep, densityStepEnd, sth, s0th,
            thickness_sampling, phi_matrix, "n")

        # print("density0, density", density0, density)
        numLoopIteration = 0

        while 1:
            if np.abs(density - density0) > density / 25:
                # print("First")
                scaleStep = 0.006
                densityStep = density / 10
                WSamplestep = 0.0008
                WRefstep = 0.0008
            elif np.abs(density - density0) > density / 75:
                # print("Second")
                scaleStep = 0.0006
                densityStep = density / 100
                WSamplestep = 0.0002
                WRefstep = 0.0002
            else:
                # print("Third")
                scaleStep = 0.00006
                densityStep = density / 1000
                WSamplestep = 0.0001
                WRefstep = 0.0001

            scaleFactor = Minimization.OptimizeScale(
                self.Q, self.I_Q, self.Ibkg_Q, self.J_Q, self.Iincoh_Q,
                self.fe_Q, self.ui.maxQ.value(), self.ui.minQ.value(),
                self.ui.QmaxIntegrate.value(), self.Ztot, density,
                scaleFactor, self.Sinf, self.ui.smoothingFactor.value(),
                self.ui.rmin.value(), self.dampingFunct, Fintra_r,
                self.ui.iterations.value(), scaleStep, sth, s0th,
                thickness_sampling, phi_matrix, "n")

            density0 = density

            density = Minimization.OptimizeDensity(
                self.Q, self.I_Q, self.Ibkg_Q, self.J_Q, self.Iincoh_Q,
                self.fe_Q, self.ui.maxQ.value(), self.ui.minQ.value(),
                self.ui.QmaxIntegrate.value(), self.Ztot, density0,
                scaleFactor, self.Sinf, self.ui.smoothingFactor.value(),
                self.ui.rmin.value(), self.dampingFunct, Fintra_r,
                self.ui.iterations.value(), densityStep, density / 250, sth,
                s0th, thickness_sampling, phi_matrix, "n")

            numLoopIteration += 1
            # print("numLoopIteration", numLoopIteration, scaleFactor, density)
            if (np.abs(density - density0) > np.abs(
                    density / 2500)) and (numLoopIteration <= 30):
                continue
            else:
                break

        # print("final scale", scaleFactor, "final density", density)

        self.ui.scaleFactorValue.setValue(scaleFactor)
        self.ui.densityValue.setValue(density)

        Isample_Q = MainFunctions.calc_IsampleQ(self.I_Q, scaleFactor,
                                                self.Ibkg_Q)
        alpha = MainFunctions.calc_alpha(
            self.J_Q[self.Q <= self.ui.QmaxIntegrate.value()], self.Sinf,
            self.Q[self.Q <= self.ui.QmaxIntegrate.value()],
            Isample_Q[self.Q <= self.ui.QmaxIntegrate.value()],
            self.fe_Q[self.Q <= self.ui.QmaxIntegrate.value()], self.Ztot,
            density)
        Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, self.Iincoh_Q)

        S_Q = MainFunctions.calc_SQ(Icoh_Q, self.Ztot, self.fe_Q, self.Sinf,
                                    self.Q, self.ui.minQ.value(),
                                    self.ui.QmaxIntegrate.value(),
                                    self.ui.maxQ.value())

        Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(
            self.Q, S_Q, self.Sinf, self.ui.smoothingFactor.value(),
            self.ui.minQ.value(), self.ui.QmaxIntegrate.value(),
            self.ui.maxQ.value())

        SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(Ssmooth_Q, self.Sinf,
                                                    self.dampingFunct)

        i_Q = MainFunctions.calc_iQ(SsmoothDamp_Q, self.Sinf)

        Qi_Q = self.Q * i_Q
        r, F_r = MainFunctions.calc_Fr(
            self.Q[self.Q <= self.ui.QmaxIntegrate.value()],
            Qi_Q[self.Q <= self.ui.QmaxIntegrate.value()])
        Fopt_r, deltaFopt_r = Optimization.calc_optimize_Fr(
            self.ui.iterations.value(), F_r, Fintra_r, density,
            i_Q[self.Q <= self.ui.QmaxIntegrate.value()],
            self.Q[self.Q <= self.ui.QmaxIntegrate.value()], self.Sinf,
            self.J_Q[self.Q <= self.ui.QmaxIntegrate.value()], r,
            self.ui.rmin.value(), "n")

        Scorr_Q = MainFunctions.calc_SQCorr(Fopt_r, r, self.Q, self.Sinf)

        self.ui.distfuncPlot.canvas.ax.plot(r,
                                            Fopt_r,
                                            "g",
                                            label=r"$F_{opt}(r)$")
        self.ui.distfuncPlot.canvas.ax.legend()
        self.ui.distfuncPlot.canvas.draw()

        self.ui.factorPlot.canvas.ax.plot(self.Q,
                                          Scorr_Q,
                                          "g",
                                          label=r"$S_{opt}(Q)$")
        self.ui.factorPlot.canvas.ax.legend()
        self.ui.factorPlot.canvas.draw()
예제 #23
0
def OptimizeDensity(Q, I_Q, Ibkg_Q, J_Q, Iincoh_Q, fe_Q, minQ, QmaxIntegrate,
                    maxQ, Ztot, density, scaleFactor, Sinf, smoothingFactor,
                    rmin, dampingFunction, Fintra_r, iterations, densityStep,
                    sth, s0th, mccFlag, thickness_sampling, phi_matrix):
    """Function for the density optimization.

    Q                  : numpy array
                         momentum transfer (nm^-1)
    I_Q                : numpy array
                         measured scattering intensity 
    Ibkg_Q             : numpy array
                         background scattering intensity
    J_Q                : numpy array
                         J(Q)
    Iincoh_Q           : numpy array
                         incoherent scattering intensity
    fe_Q               : numpy array
                         effective electric form factor
    minQ               : float
                         minimum Q value
    QmaxIntegrate      : float
                         maximum Q value for the intagrations
    maxQ               : float
                         maximum Q value
    Ztot               : int
                         total Z number
    density            : float
                         average atomic density
    scaleFactor        : float
                         scale factor
    Sinf               : float
                         value of S(Q) for Q->inf
    smoothingFactor    : float
                         smoothing factor
    rmin               : float
                         r cut-off value (nm)
    dampingFunction    : numpy array
                         damping function
    Fintra_r           : numpy array
                         intramolecular contribution of F(r)
    iterations         : int
                         number of iterations
    scaleStep
    sth
    s0th
    thickness_sampling : float
    phi_matrix
    MCC_flag
    """

    numSample = 23

    if mccFlag.lower() == "y":
        T_MCC_sth, T_MCC_corr_factor_bkg = Geometry.MCC_correction(
            sth, s0th, thickness_sampling, phi_matrix)

        I_Q = I_Q / T_MCC_sth
        Ibkg_Q = Ibkg_Q * T_MCC_corr_factor_bkg / (T_MCC_sth)

    flag = 0
    # Loop for the range shifting
    while 1:
        flag += 1
        print("iter flag ", flag)

        densityArray = UtilityAnalysis.makeArrayLoop(density, densityStep)
        chi2Array = np.zeros(numSample)

        for i in range(numSample):
            print("sample ", i, densityArray[i])

            # ------------------Kaplow method for scale--------------------

            Isample_Q = MainFunctions.calc_IsampleQ(I_Q, scaleFactor, Ibkg_Q)
            alpha = MainFunctions.calc_alpha(J_Q[Q <= QmaxIntegrate], Sinf,
                                             Q[Q <= QmaxIntegrate],
                                             Isample_Q[Q <= QmaxIntegrate],
                                             fe_Q[Q <= QmaxIntegrate], Ztot,
                                             densityArray[i])
            Icoh_Q = MainFunctions.calc_Icoh(alpha, Isample_Q, Iincoh_Q)

            S_Q = MainFunctions.calc_SQ(Icoh_Q, Ztot, fe_Q, Sinf, Q, minQ,
                                        QmaxIntegrate, maxQ)

            Ssmooth_Q = UtilityAnalysis.calc_SQsmoothing(
                Q, S_Q, Sinf, smoothingFactor, minQ, QmaxIntegrate, maxQ)

            SsmoothDamp_Q = UtilityAnalysis.calc_SQdamp(
                Ssmooth_Q, Sinf, dampingFunction)

            i_Q = MainFunctions.calc_iQ(SsmoothDamp_Q, Sinf)

            Qi_Q = Q * i_Q
            r, F_r = MainFunctions.calc_Fr(Q[Q <= QmaxIntegrate],
                                           Qi_Q[Q <= QmaxIntegrate])

            # r, F_r = MainFunctions.calc_Fr(Q[Q<=QmaxIntegrate],
            #     Qi_Q[Q<=QmaxIntegrate])

            Fopt_r, deltaFopt_r = Optimization.calc_optimize_Fr(
                iterations, F_r, Fintra_r, densityArray[i],
                i_Q[Q <= QmaxIntegrate], Q[Q <= QmaxIntegrate], Sinf,
                J_Q[Q <= QmaxIntegrate], r, rmin, "n")

            deltaFopt_r[np.where(r >= rmin)] = 0.0
            chi2Array[i] = np.mean(deltaFopt_r**2)

        # --------------------Range shifting selection --------------------

        # densityIdx = np.argmin(chi2Array)
        # density = densityArray[densityIdx] - densityStep*1.1

        # nearIdx, nearEl = UtilityAnalysis.find_nearest(densityArray, density)

        plt.scatter(densityArray, chi2Array)
        plt.grid(True)
        plt.show()

        maxLimit = 10**5
        if np.amax(chi2Array) >= maxLimit:
            densityArray = densityArray[0:np.argmax(chi2Array >= maxLimit)]
            chi2Array = chi2Array[0:np.argmax(chi2Array >= maxLimit)]

        # print(np.argmin(chi2Array))

        if np.argmin(chi2Array) < 6:
            # print("bug")
            density -= densityStep * 10
        if np.argmin(chi2Array) > 16:
            density += densityStep * 10

        if (np.argmin(chi2Array) >= 6 and np.argmin(chi2Array) <= 16):
            break
        else:
            continue

    # ------------------------chi2 curve fit for scale-------------------------

    #xFit, yFit, density, chi2Min = chi2Fit(densityArray, chi2Array)
    xFit, yFit, density, chi2 = IgorFunctions.chi2Fit(density, densityArray,
                                                      chi2Array)

    print("final density", density)

    plt.scatter(densityArray, chi2Array)
    plt.plot(xFit, yFit)
    plt.grid(True)
    plt.show()

    return density