Python AccSignal Exemples

Exemple #1

def test_cumulative_absolute_velocity():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    acc_signal.generate_cumulative_stats()
    true_cav = 8.53872
    assert np.isclose(acc_signal.cav, true_cav, rtol=0.0001)

Exemple #2

def test_arias_intensity():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    acc_signal.generate_cumulative_stats()
    true_arias_intensity = 0.63398
    assert np.isclose(acc_signal.arias_intensity,
                      true_arias_intensity,
                      rtol=0.0001)

Exemple #3

Fichier : examples_acc_signal.py Projet : wangyf/eqsig

def show_test_motion():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    acc_signal.generate_displacement_and_velocity_series()
    bf, sp = plt.subplots(3)
    sp[0].plot(acc_signal.time, acc_signal.values)
    sp[1].plot(acc_signal.time, acc_signal.velocity)
    sp[2].plot(acc_signal.time, acc_signal.displacement)
    plt.show()

Exemple #4

def test_duration_stats():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    acc_signal.generate_duration_stats()

    assert np.isclose(acc_signal.t_595, 20.99)  # eqsig==0.5.0
    assert np.isclose(acc_signal.t_b01, 38.27)  # eqsig==0.5.0
    assert np.isclose(acc_signal.t_b05, 15.41)  # eqsig==0.5.0
    assert np.isclose(acc_signal.t_b10, 8.41)  # eqsig==0.5.0

Exemple #5

Fichier : test_stockwell.py Projet : wangyf/eqsig

def test_stockwell_transform_then_inverse():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename, skiprows=2)
    acc_signal = AccSignal(rec, motion_step)
    acc2_signal = interp_to_approx_dt(acc_signal, 0.1)
    acc2_signal.swtf = stockwell.transform(acc2_signal.values)
    assert len(acc2_signal.swtf[0]) == acc2_signal.npts
    inv_signal = AccSignal(stockwell.itransform(acc2_signal.swtf), acc2_signal.dt)

    norm_abs_error = np.sum(abs(acc2_signal.values - inv_signal.values)) / acc2_signal.npts
    assert norm_abs_error < 0.008

Exemple #6

def test_peak_values():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    acc_signal.generate_peak_values()
    true_pga = 1.41
    true_pgv = 0.26006
    true_pgd = 0.07278134  # eqsig==0.4.12
    assert np.isclose(acc_signal.pga, true_pga, rtol=0.001)
    assert np.isclose(acc_signal.pgv, true_pgv, rtol=0.0001), acc_signal.pgv
    assert np.isclose(acc_signal.pgd, true_pgd, rtol=0.0001), acc_signal.pgd

Exemple #7

Fichier : multiple.py Projet : mtoqeerpk/eqsig

    def __init__(self, values, dt, names=[], master_index=0, stypes="custom", **kwargs):

        self.freq_range = np.array(kwargs.get('freq_range', [0.1, 20]))
        lvt = np.log10(1.0 / self.freq_range)
        if stypes == "custom" or stypes == "acc":
            stypes = [stypes] * len(values)
        self.response_times = kwargs.get('resp_times', np.logspace(lvt[1], lvt[0], 31, base=10))
        if master_index < 0:
            raise ValueError("master_index must be positive")
        if master_index > len(values) - 1:
            raise ValueError("master_index: %i, out of bounds, maximum value: %i" % (master_index, len(signals) - 1))
        self.master_index = master_index
        # if len(signals) != len(steps):
        #     raise ValueError("Length of signals: %i, must match length of steps: %i" % (len(signals), len(steps)))

        # self.master = Record(master_motion, master_step, response_times=self.response_times)
        shortage = len(values) - len(names)
        self.names = list(names)
        for i in range(shortage):
            self.names.append("m%i" % (len(names) + i))
        self.master = self.names[master_index]
        self.dt = dt
        self.signals = OrderedDict()
        for s in range(len(values)):
            if stypes[s] == "acc":
                self.signals[self.names[s]] = AccSignal(values[s], dt, self.names[s], response_times=self.response_times)
            else:
                self.signals[self.names[s]] = Signal(values[s], dt, self.names[s])

Exemple #8

Fichier : test_single_signal_w_motion.py Projet : wangyf/eqsig

def test_fourier_spectra_with_motion():
    record_path = TEST_DATA_DIR

    record_filename = 'test_motion_dt0p01.txt'
    motion_dt = 0.01
    rec = np.loadtxt(record_path + record_filename, skiprows=2)

    rec2 = np.zeros(2**13)
    rec2[:len(rec)] = rec
    asig = AccSignal(-rec, motion_dt)

    nfreq = len(asig.fa_spectrum)
    test_filename = 'test_motion_true_fourier_spectra.csv'
    data = np.loadtxt(record_path + test_filename, skiprows=1, delimiter=",")
    freqs = data[:nfreq - 1, 0]
    fa = data[:nfreq - 1, 1]
    phase = data[:nfreq - 1, 2]

    fa_eqsig = abs(asig.fa_spectrum)
    freq_eqsig = asig.fa_frequencies
    org_phases = np.angle(asig.fa_spectrum)
    ss_phases = np.angle(np.fft.rfft(rec2))[:len(org_phases)] + 0.0001

    assert np.isclose(freqs[0], freq_eqsig[1], rtol=0.001), freqs[0]
    assert np.isclose(freqs[20], freq_eqsig[21], rtol=0.0001)
    assert np.isclose(freqs[-1], freq_eqsig[-1], rtol=0.001)
    for i in range(len(fa)):
        assert np.isclose(fa[i], fa_eqsig[i + 1], atol=0.00001), i

Exemple #9

Fichier : functions.py Projet : wangyf/eqsig

def fas2signal(fas, dt, stype="signal"):
    """
    Convert a fourier spectrum to time series signal

    Parameters
    ----------
    fas: array_like of img floats
        Positive part only
    dt: float
        time step of time series
    stype: str
        If 'signal' then return Signal, else return AccSignal
    """
    from eqsig.single import Signal, AccSignal
    n = 2 * len(fas)
    a = np.zeros(2 * len(fas), dtype=complex)
    a[1:n // 2] = fas[1:]
    a[n // 2 + 1:] = np.flip(np.conj(fas[1:]), axis=0)
    a /= dt
    s = np.fft.ifft(a)
    npts = int(2 ** (np.log(n) / np.log(2)))
    s = s[:npts]
    if stype == 'signal':
        return Signal(s, dt)
    else:
        return AccSignal(s, dt)

Exemple #10

Fichier : examples_acc_signal.py Projet : mgrubisic/eqsig

def show_response_spectra_at_high_frequencies():
    record_path = TEST_DATA_DIR
    test_filename = 'test_motion_true_spectra_acc.csv'
    data = np.loadtxt(record_path + test_filename, skiprows=1, delimiter=",")
    times = data[:40, 0]
    ss_s_a = data[:40, 1]

    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    # acc_signal = AccSignal(rec, motion_step, response_times=times)
    # s_a = acc_signal.s_a
    #
    # a_times = acc_signal.response_times
    # s_d, s_v, s_a = dh.pseudo_response_spectra(rec, motion_step, times, xi=0.05)
    # s_d, s_v, s_a = dh.true_response_spectra(rec, motion_step, times, xi=0.05)
    acc_signal = AccSignal(rec, motion_step, response_times=times)
    s_a = acc_signal.s_a

    s_a_in_g = s_a / 9.81

    # srss1 = sum(abs(s_a_in_g - ss_s_a))
    plt.plot(times, s_a_in_g, label="eqsig")
    plt.plot(times, ss_s_a, label="true-ish")
    plt.legend()
    plt.show()

Exemple #11

def load_asig(ffp, load_label=False, m=1.0):
    """
    Loads an ``AccSignal`` that was saved in eqsig input format.

    Parameters
    ----------
    ffp: str
        Full file path to output file
    load_label: bool
        if true then get label from file
    m: float (default=1.0)
        Scale factor to apply to time series data when loading

    Returns
    -------
    asig: eqsig.AccSignal
    """
    vals, dt = load_values_and_dt(ffp)
    if load_label:
        a = open(ffp)
        label = a.read().splitlines()[0]
        a.close()
    else:
        label = 'm1'
    return AccSignal(vals * m, dt, label=label)

Exemple #12

Fichier : test_single_signal_w_motion.py Projet : wangyf/eqsig

def test_fourier_spectra_stable_against_aliasing():
    record_path = TEST_DATA_DIR

    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename, skiprows=2)
    rec2 = np.zeros(2**13)
    rec2[:len(rec)] = rec
    org_signal = AccSignal(rec, motion_step)
    extended_signal = AccSignal(rec2, motion_step)

    rec_split = []
    for i in range(int(len(rec2) / 2)):
        rec_split.append(rec2[i * 2])

    acc_split = AccSignal(rec_split, motion_step * 2)

    org_fa = abs(org_signal.fa_spectrum)
    split_fa = abs(acc_split.fa_spectrum)
    ext_fa = abs(extended_signal.fa_spectrum)

    org_freq = abs(org_signal.fa_frequencies)
    split_freq = abs(acc_split.fa_frequencies)
    ext_freq = abs(extended_signal.fa_frequencies)

    for i in range(len(org_signal.fa_spectrum)):

        if i > 1830:
            abs_tol = 0.03
        else:
            abs_tol = 0.02

        assert np.isclose(org_freq[i], ext_freq[i])
        assert np.isclose(org_fa[i], ext_fa[i])

        if i < 2048:
            assert np.isclose(org_freq[i], split_freq[i])
            assert np.isclose(org_fa[i], split_fa[i], atol=abs_tol), i

Exemple #13

Fichier : examples_acc_signal.py Projet : wangyf/eqsig

def show_fourier_spectra_stable_against_aliasing():
    record_path = TEST_DATA_DIR

    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    rec2 = np.zeros(2**13)
    rec2[:len(rec)] = rec
    org_signal = AccSignal(rec, motion_step)
    extended_signal = AccSignal(rec2, motion_step)

    rec_split = []
    for i in range(int(len(rec2) / 2)):
        rec_split.append(rec2[i * 2])

    acc_split = AccSignal(rec_split, motion_step * 2)

    bf, sp = plt.subplots(2)
    sp[0].plot(org_signal.time, org_signal.values)
    sp[0].plot(extended_signal.time, extended_signal.values)
    sp[0].plot(acc_split.time, acc_split.values)

    sp[1].plot(org_signal.fa_frequencies,
               abs(org_signal.fa_spectrum),
               lw=0.7,
               label="original")
    sp[1].plot(acc_split.fa_frequencies,
               abs(acc_split.fa_spectrum),
               lw=0.7,
               label="split")
    sp[1].plot(extended_signal.fa_frequencies,
               abs(extended_signal.fa_spectrum),
               lw=0.7,
               label="full")

    plt.legend()
    plt.show()

Exemple #14

Fichier : test_single_signal_w_noise.py Projet : mgrubisic/eqsig

def load_test_record_from_file(record_path, record_filename, scale=1):
    a = open(record_path + record_filename, 'r')
    b = a.readlines()
    a.close()

    acc = []
    motion_step = float(b[0].split("=")[1])
    print('values dt: ', motion_step)
    for i in range(len(b)):
        if i > 3:
            dat = b[i].split()
            for j in range(len(dat)):
                acc.append(float(dat[j]) * scale)

    rec = AccSignal(acc, motion_step)
    return rec

Exemple #15

Fichier : test_single_signal_w_motion.py Projet : mgrubisic/eqsig

def rewrite_fourier_spectra_test_file():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    fa_amplitudes = abs(acc_signal.fa_spectrum)
    fa_phases = np.angle(acc_signal.fa_spectrum)

    paras = []
    for i in range(len(acc_signal.fa_frequencies)):
        paras.append("%.5f,%.5f,%.5f" % (acc_signal.fa_frequencies[i], fa_amplitudes[i], fa_phases[i]))
    outfile_name = record_path + "test_motion_dt0p01_fas.txt"
    outfile = open(outfile_name, "w")
    outfile.write("\n".join(paras))
    outfile.close()

Exemple #16

def test_response_spectra_at_high_frequencies():
    record_path = TEST_DATA_DIR
    test_filename = 'test_motion_true_spectra_acc.csv'
    data = np.loadtxt(record_path + test_filename, skiprows=1, delimiter=",")
    times = data[:40, 0]
    ss_s_a = data[:40, 1]

    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step, response_times=times)
    s_a = acc_signal.s_a
    s_a_in_g = s_a / 9.81
    a_times = acc_signal.response_times
    assert len(times) == len(a_times)
    srss1 = sum(abs(s_a_in_g - ss_s_a))
    assert srss1 < 0.01 * 40, srss1

Exemple #17

def rewrite_response_spectra_eqsig_test_file():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step, response_times=(0.1, 5.))

    s_a = acc_signal.s_a
    s_d = acc_signal.s_d
    times = acc_signal.response_times

    paras = []
    for i in range(len(times)):
        paras.append("%.5f,%.5f,%.5f" % (times[i], s_a[i], s_d[i]))
    outfile_name = record_path + "test_motion_dt0p01_rs.txt"
    outfile = open(outfile_name, "w")
    outfile.write("\n".join(paras))
    outfile.close()

Exemple #18

Fichier : test_single_signal_w_motion.py Projet : mgrubisic/eqsig

def test_fourier_spectra():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    fa_amplitudes = abs(acc_signal.fa_spectrum)
    fa_phases = np.angle(acc_signal.fa_spectrum)

    paras = []
    for i in range(len(acc_signal.fa_frequencies)):
        paras.append("%.5f,%.5f,%.5f" % (acc_signal.fa_frequencies[i], fa_amplitudes[i], fa_phases[i]))

    testfile_name = record_path + "test_motion_dt0p01_fas.txt"
    testfile = open(testfile_name, "r")
    test_lines = testfile.readlines()
    for i, line in enumerate(test_lines):
        line = line.replace("\n", "")
        assert line == paras[i], i

Exemple #19

Fichier : functions.py Projet : mgrubisic/eqsig

def fas2signal(fas, dt, stype="signal"):
    """
    Convert a fourier spectrum to time series signal

    :param fas: positive part only
    :param dt: time step of time series
    :return:
    """
    n = 2 * len(fas)
    a = np.zeros(2 * len(fas), dtype=complex)
    a[1:n // 2] = fas[1:]
    a[n // 2 + 1:] = np.flip(np.conj(fas[1:]), axis=0)
    a /= dt
    s = np.fft.ifft(a)
    npts = int(2**(np.log(n) / np.log(2)))
    s = s[:npts]
    if stype == 'signal':
        return Signal(s, dt)
    else:
        return AccSignal(s, dt)

Exemple #20

def test_response_spectra_versus_old_eqsig_version():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    s_a = acc_signal.s_a
    s_d = acc_signal.s_d
    times = acc_signal.response_times

    paras = []
    for i in range(len(times)):
        paras.append("%.5f,%.5f,%.5f" % (times[i], s_a[i], s_d[i]))

    testfile_name = record_path + "test_motion_dt0p01_rs.txt"
    testfile = open(testfile_name, "r")
    test_lines = testfile.readlines()
    for i, line in enumerate(test_lines):
        line = line.replace("\n", "")
        assert line == paras[i], i

Exemple #21

def test_displacement_velocity():
    record_path = TEST_DATA_DIR
    record_filename = 'test_motion_dt0p01.txt'
    motion_step = 0.01
    rec = np.loadtxt(record_path + record_filename)
    acc_signal = AccSignal(rec, motion_step)
    # Compare time series
    test_filename = 'test_motion_avd.csv'
    data = np.loadtxt(record_path + test_filename, skiprows=1, delimiter=",")
    time = data[:, 0]
    velocity = data[:, 2]
    displacement = data[:, 3]
    assert len(time) == len(acc_signal.time)
    abs_velocity_diff = abs(acc_signal.velocity - velocity)
    cum_velocity_diff = sum(abs_velocity_diff)
    max_velocity_diff = max(abs_velocity_diff)
    assert cum_velocity_diff < 0.03, cum_velocity_diff
    assert max_velocity_diff < 0.00006, max_velocity_diff
    abs_disp_diff = abs(acc_signal.displacement - displacement)
    cum_disp_diff = sum(abs_disp_diff)
    max_disp_diff = max(abs_disp_diff)
    assert cum_disp_diff < 0.02, cum_disp_diff
    assert max_disp_diff < 0.00002, max_disp_diff

    # Compare time series versus true
    test_filename = 'test_motion_avd.csv'
    data = np.loadtxt(record_path + test_filename, skiprows=1, delimiter=",")
    time = data[:, 0]
    velocity = data[:, 2]
    displacement = data[:, 3]
    assert len(time) == len(acc_signal.time)
    abs_velocity_diff = abs(acc_signal.velocity - velocity)
    cum_velocity_diff = sum(abs_velocity_diff)
    max_velocity_diff = max(abs_velocity_diff)
    assert cum_velocity_diff < 0.03, cum_velocity_diff
    assert max_velocity_diff < 0.00006, max_velocity_diff
    abs_disp_diff = abs(acc_signal.displacement - displacement)
    cum_disp_diff = sum(abs_disp_diff)
    max_disp_diff = max(abs_disp_diff)
    assert cum_disp_diff < 0.02, cum_disp_diff
    assert max_disp_diff < 0.00002, max_disp_diff

Exemple #22

Fichier : multiple.py Projet : mgrubisic/eqsig

def combine_at_angle(acc_sig_ns, acc_sig_we, angle):
    off_rad = np.radians(angle)
    combo = acc_sig_ns.values * np.cos(off_rad) + acc_sig_we.values * np.sin(
        off_rad)
    new_sig = AccSignal(combo, acc_sig_ns.dt)
    return new_sig

Exemple #23

def load_signal(ffp, astype='sig'):
    vals, dt = load_values_and_dt(ffp)
    if astype == "signal":
        return Signal(vals, dt)
    elif astype == "acc_sig":
        return AccSignal(vals, dt)