Exemple #1
0
def peak(line):
    if (len(sys.argv) != 2):
        print('Usage: fit_calibrated_peaks.py [run number]')
        sys.exit()

    # take calibration parameter for the 'calibration.py' output
    with open("calDB.json") as f:
        calDB = json.load(f)
    cal = calDB["cal_pass1"]["1"]["p1cal"]

    with open("runDB.json") as f:
        runDB = json.load(f)
    meta_dir = os.path.expandvars(runDB["meta_dir"])
    tier_dir = os.path.expandvars(runDB["tier_dir"])

    #df =  pd.read_hdf("{}/Spectrum_{}_2.hdf5".format(meta_dir,sys.argv[1]), key="df")
    df = pd.read_hdf("{}/t2_run{}.h5".format(tier_dir, sys.argv[1]))

    df['e_cal'] = cal * df['e_ftp']

    df = df.loc[(df.index > 1000) & (df.index < 500000)]

    def gauss(x, mu, sigma, A=1):
        """
        define a gaussian distribution, w/ args: mu, sigma, area (optional).
        """
        return A * (1. / sigma / np.sqrt(2 * np.pi)) * np.exp(-(x - mu)**2 /
                                                              (2. * sigma**2))

    line_min = 0.995 * line
    line_max = 1.005 * line
    nbin = 60
    res = 6.3e-4 * line + 0.85  # empirical energy resolution curve from experience

    hist, bins, var = pgh.get_hist(df['e_cal'],
                                   range=(line_min, line_max),
                                   dx=(line_max - line_min) / nbin)
    pgh.plot_hist(hist, bins, var=hist, label="data", color='blue')
    pars, cov = pga.fit_hist(gauss,
                             hist,
                             bins,
                             var=hist,
                             guess=[line, res, 50])
    pgu.print_fit_results(pars, cov, gauss)
    pgu.plot_func(gauss, pars, label="chi2 fit", color='red')

    FWHM = '%.2f' % Decimal(pars[1] * 2)
    FWHM_uncertainty = '%.2f' % Decimal(np.sqrt(cov[1][1]) * 2)
    peak = '%.2f' % Decimal(pars[0])
    peak_uncertainty = '%.2f' % Decimal(np.sqrt(cov[0][0]))
    residual = '%.2f' % abs(line - float(peak))

    label_01 = 'Peak = ' + str(peak) + r' $\pm$ ' + str(peak_uncertainty)
    label_02 = 'FWHM = ' + str(FWHM) + r' $\pm$ ' + str(FWHM_uncertainty)
    labels = [
        label_01,
        label_02,
    ]

    plt.xlim(line_min, line_max)
    plt.xlabel('Energy (keV)', ha='right', x=1.0)
    plt.ylabel('Counts', ha='right', y=1.0)

    plt.tight_layout()
    plt.hist(df['e_cal'], range=(line_min, line_max), bins=nbin)
    plt.legend(labels, frameon=False, loc='upper right', fontsize='small')

    return peak, FWHM
Exemple #2
0
def peak(df, runDB, calDB, r, line, p=[1, 0], plotit=False):

    cal = 0.04998  # calDB["cal_pass1"]["1"]["p1cal"]
    meta_dir = os.path.expandvars(runDB["meta_dir"])
    tier_dir = os.path.expandvars(runDB["tier2_dir"])

    df['e_cal'] = p[0] * (cal * df['e_ftp']) + p[1]
    #h = df.hist('e_cal',bins=2000)
    #plt.yscale('log')
    df = df.loc[(df.index > 1000) & (df.index < 500000)]

    def gauss(x, mu, sigma, A=1):
        """
       define a gaussian distribution, w/ args: mu, sigma, area (optional).
       """
        return A * (1. / sigma / np.sqrt(2 * np.pi)) * np.exp(-(x - mu)**2 /
                                                              (2. * sigma**2))

    line_min = 0.995 * line
    line_max = 1.005 * line
    nbin = 60
    res = 6.3e-4 * line + 0.85  # empirical energy resolution curve from experience

    hist, bins, var = pgh.get_hist(df['e_cal'],
                                   range=(line_min, line_max),
                                   dx=(line_max - line_min) / nbin)
    if plotit:
        pgh.plot_hist(hist, bins, var=hist, label="data", color='blue')
    pars, cov = pga.fit_hist(gauss,
                             hist,
                             bins,
                             var=hist,
                             guess=[line, res, 50])
    pgu.print_fit_results(pars, cov, gauss)
    if plotit:
        pgu.plot_func(gauss, pars, label="chi2 fit", color='red')

    FWHM = '%.2f' % Decimal(
        pars[1] * 2. * np.sqrt(2. * np.log(2)))  # convert sigma to FWHM
    FWHM_uncertainty = '%.2f' % Decimal(
        np.sqrt(cov[1][1]) * 2. * np.sqrt(2. * np.log(2)))
    peak = '%.2f' % Decimal(pars[0])
    peak_uncertainty = '%.2f' % Decimal(np.sqrt(cov[0][0]))
    residual = '%.2f' % abs(line - float(peak))

    if plotit:
        label_01 = 'Peak = ' + str(peak) + r' $\pm$ ' + str(peak_uncertainty)
        label_02 = 'FWHM = ' + str(FWHM) + r' $\pm$ ' + str(FWHM_uncertainty)
        labels = [
            label_01,
            label_02,
        ]

        plt.xlim(line_min, line_max)
        plt.xlabel('Energy (keV)', ha='right', x=1.0)
        plt.ylabel('Counts', ha='right', y=1.0)

        plt.tight_layout()
        plt.hist(df['e_cal'], range=(line_min, line_max), bins=nbin)
        plt.legend(labels, frameon=False, loc='upper right', fontsize='small')

        plt.savefig(meta_dir + '/plots/lineFit_' + str(r) + '.png')
    return peak, FWHM
Exemple #3
0
def peak_352():

    if (len(sys.argv) != 2):
        print('Usage: fit_bkg_peaks.py [run number]')
        sys.exit()

    with open("runDB.json") as f:
        runDB = json.load(f)
    meta_dir = os.path.expandvars(runDB["meta_dir"])

    #df =  pd.read_hdf("{}/Spectrum_280-329.hdf5".format(meta_dir), key="df")
    df = pd.read_hdf("{}/Spectrum_{}.hdf5".format(meta_dir, sys.argv[1]),
                     key="df")

    def gauss(x, mu, sigma, A=1):
        """
        define a gaussian distribution, w/ args: mu, sigma, area (optional).
        """
        return A * (1. / sigma / np.sqrt(2 * np.pi)) * np.exp(-(x - mu)**2 /
                                                              (2. * sigma**2))

    def radford_peak(x, mu, sigma, hstep, htail, tau, bg0, a=1):
        """
        David Radford's HPGe peak shape function
        """
        # make sure the fractional amplitude parameters stay reasonable...
        if htail < 0 or htail > 1:
            return np.zeros_like(x)
        if hstep < 0 or hstep > 1:
            return np.zeros_like(x)

        bg_term = bg0  #+ x*bg1
        if np.any(bg_term < 0):
            return np.zeros_like(x)

        # compute the step and the low energy tail
        step = a * hstep * erfc((x - mu) / (sigma * np.sqrt(2)))
        le_tail = a * htail
        le_tail *= erfc((x - mu) / (sigma * np.sqrt(2)) + sigma /
                        (tau * np.sqrt(2)))
        le_tail *= np.exp((x - mu) / tau)
        le_tail /= (2 * tau * np.exp(-(sigma / (np.sqrt(2) * tau))**2))

        # add up all the peak shape components
        return (1 - htail) * gauss(x, mu, sigma, a) + bg_term + step + le_tail

    hist, bins, var = pgh.get_hist(df['e_cal'], range=(345, 360), dx=0.5)
    pgh.plot_hist(hist, bins, var=hist, label="data")
    pars, cov = pga.fit_hist(radford_peak,
                             hist,
                             bins,
                             var=hist,
                             guess=[352, 1.05, 0.001, 0.02, 500, 1000, 40000])
    pgu.print_fit_results(pars, cov, radford_peak)
    pgu.plot_func(radford_peak, pars, label="chi2 fit", color='red')
    #x_vals = np.arange(345,360,0.5)
    #plt.plot(x_vals, radford_peak(x_vals, 353, 1.05, .001, 0.02, 500, 1000, 40000))

    FWHM = '%.2f' % Decimal(pars[1] * 2)
    FWHM_uncertainty = '%.2f' % Decimal(np.sqrt(cov[1][1]) * 2)
    peak = '%.2f' % Decimal(pars[0])
    peak_uncertainty = '%.2f' % Decimal(np.sqrt(cov[0][0]))
    residual = '%.2f' % (351.93 - float(peak))

    #chi_2_element_list = []
    #for i in range(len(hist)):
    #chi_2_element = abs((radford_peak(bins[i], *pars) - hist[i])**2/radford_peak(bins[i], *pars))
    #chi_2_element_list.append(chi_2_element)
    #chi_2 = sum(chi_2_element_list)
    #reduced_chi_2 = '%.2f' % Decimal(chi_2/len(hist))

    label_01 = '351.93 keV peak fit'
    label_02 = 'FWHM = ' + str(FWHM) + r' $\pm$ ' + str(FWHM_uncertainty)
    label_03 = 'Peak = ' + str(peak) + r' $\pm$ ' + str(peak_uncertainty)
    label_04 = 'Residual = ' + str(residual) + r' $\pm$ ' + str(
        peak_uncertainty)
    colors = ['red', 'red', 'red', 'red']
    lines = [Line2D([0], [0], color=c, lw=2) for c in colors]
    labels = [label_01, label_02, label_03, label_04]

    plt.xlim(345, 360)
    plt.ylim(0, plt.ylim()[1])
    plt.xlabel('Energy (keV)', ha='right', x=1.0)
    plt.ylabel('Counts', ha='right', y=1.0)

    plt.tight_layout()
    #plt.semilogy()
    plt.legend(lines,
               labels,
               frameon=False,
               loc='upper right',
               fontsize='small')
    plt.show()