コード例 #1
0
ファイル: reflectivity.py プロジェクト: EvanBianco/modelr
def create_theta_spike(pad, prop0, prop1, theta, f, points, reflectivity_method):
    '''
    Create a 2D array where the first dimension is time and the second is angle.

    :param pad: pad the array top and bottom in ms
    :param prop0: rock properties 1
    :param prop1: rock properties 1
    :param theta: array of angles
    :param f: the frequency for the wavelet
    '''

    nsamples = (2 * pad)

    array_amp = np.zeros([nsamples, theta.size])

    Rp = reflectivity_method(prop0, prop1, theta)
    array_amp[pad, :] += Rp

    r = ricker_alg(.2,points, f)

    warray_amp = np.zeros([max(array_amp.shape[0], r.shape[0]), array_amp.shape[1]])

    for i in range(theta.size):
        warray_amp[:, i] = np.convolve(array_amp[:, i], r, mode='same')

    return np.array(warray_amp)
コード例 #2
0
ファイル: one_spike.py プロジェクト: EvanBianco/modelr
def run_script(args):
    
    matplotlib.interactive(False)
    
    array_amp = np.zeros([args.time])
    array_time = np.arange(args.time)
    
    Rpp = args.reflectivity_model(args.Rpp0, args.Rpp1, args.theta1)
    
    array_amp[args.time // 2] = Rpp
    
    r = ricker_alg(1,128, args.f)
    
    warray_amp = np.convolve(array_amp, r, mode='same')
    
    fig = plt.figure()
    
    ax1 = fig.add_subplot(111)

    ax1.plot(warray_amp, array_time)
    
    plt.title(args.title % locals())
    plt.ylabel('time (ms)')
    plt.xlabel('amplitude')
    
    ax = plt.gca()
    ax.set_ylim(ax.get_ylim()[::-1])
    ax.set_xlim(args.xlim)
    
    return return_current_figure()
コード例 #3
0
ファイル: reflectivity.py プロジェクト: EvanBianco/modelr
def create_wedge(ntraces, pad, max_thickness, prop0, prop1, theta, f, reflectivity_method):
    '''
    Create a wedge model.
    
    :param ntraces: number of traces
    :param pad: pad the array top and bottom in ms
    :param max_thickness: The thickest part of the wedge
    :param prop0: rock properties 1
    :param prop1: rock properties 1
    :param theta: angle of incidence
    :param f: the frequency for the wavelet
    '''
    scale = 10
    nsamples = (2 * pad + max_thickness) * scale
      
    array_amp = np.zeros([nsamples, ntraces])
    fwedge = np.floor(np.linspace(pad * scale, (pad + max_thickness) * scale,
                      ntraces, endpoint=False))
    wedge = np.array(fwedge, dtype=int)
    
     
    Rp0 = reflectivity_method(prop0, prop1, theta)
    Rp1 = reflectivity_method(prop1, prop0, theta)
    
    array_amp[pad * scale, :] += Rp0
    array_amp[wedge, np.arange(ntraces)] += Rp1
    
    r = ricker_alg(0.2, 100 * scale, f)
    
    warray_amp = np.zeros([max(array_amp.shape[0], r.shape[0]), array_amp.shape[1]])
    
    for i in range(ntraces):
        warray_amp[:, i] = np.convolve(array_amp[:, i], r, mode='same')
        
    return np.array(warray_amp[::scale, :])