Exemplo n.º 1
0
def integrand2(theta, E, forward, x_min, x_max, sad):
    p1 = at.klein_nishina(E, theta) * 10e30
    p2 = rd.continue_line(theta, sad, x_min, x_max)
    p3 = at.energy_limit_factor(E, theta, forward)
    p4 = at.energy_distribution(E)
    p5 = rd.continue_log(E / 1000, af.E, af.prob_NE213)
    return p1 * p2 * p3 * p4 * (1 - p5)
def integrand(E, theta_S, sad, forward, x_min, x_max):

    p1 = rd.continue_line(theta_S, sad, x_min, x_max)
    p2 = at.klein_nishina(E, theta_S)
    p3 = at.energy_limit_factor(E, theta_S, forward) * 1e35
    p4 = at.energy_distribution(E)
    #print(p1*p2*p3*p4,p1,p2,p3,p4,E,theta_S)
    return p1 * p2 * p3 * p4
Exemplo n.º 3
0
def plot_E_all():
    scale1 = 1.7
    x_min = 0
    x_max = 6000

    d = rd.read_h5py_file()
    d = rd.cut_selection(d, 9, 0, True)
    E = rd.extract_parameter(d, 1)  # + rd.extract_parameter(d, 3)
    n, bins, patches = plt.hist(E, 500)
    x = np.linspace(x_min, x_max, 200)
    y = np.array([at.energy_distribution(i) for i in x])
    y = y * np.amax(n) / np.amax(y) * scale1
    #plt.plot(x,y,label="A")

    plt.xlim(x_min, x_max)
    plt.xlabel("Detected Energy [keV]")
    plt.ylabel("Frequency [Counts/Bin]")
Exemplo n.º 4
0
def plot_E_dist(
    forward,
    num_bins=300,
):
    x_min = 0000
    x_max = 5000
    y_min = 0
    #y_max=140000
    scale1 = 1.8
    scale2 = 1

    d = rd.read_h5py_file()
    d = rd.cut_selection(d, 9, 0, forward)
    E = rd.extract_parameter(d, 1) + rd.extract_parameter(d, 3)
    n, bins, patches = plt.hist(E, num_bins)
    x = np.linspace(x_min, x_max, 100)
    y = np.array([at.energy_distribution(i) for i in x])
    y = y * np.amax(n) / np.amax(y) * scale1
    plt.plot(x, y, label="A")

    if forward:
        t_min, t_max, sad = at.fsad_min, at.fsad_max, at.fsad
    else:
        t_min, t_max, sad = at.bsad_min, at.bsad_max, at.bsad
    y2 = np.array([
        quad(integrand1, t_min, t_max, (i, forward, t_min, t_max, sad), 0,
             10e-5, 10e-5)[0] for i in x
    ])
    y2 = y2 * np.amax(n) / np.amax(y2) * scale2
    plt.plot(x, y2, label="B")

    plt.xlabel("Total Detected Energy [keV]")
    plt.ylabel("Frequency [Counts/Bin]")
    plt.legend()

    plt.xlim(x_min, x_max)
    plt.ylim(0, 50000)
Exemplo n.º 5
0
def integrand2(Energy):
    return at.energy_distribution(Energy * 1000)
Exemplo n.º 6
0
def integrand1(Energy):
    return at.energy_distribution(Energy * 1000) * rd.continue_linear_set(
        Energy, E, average_distance)
Exemplo n.º 7
0
def integrand1(theta, E, forward, x_min, x_max, sad):
    p1 = at.klein_nishina(E, theta) * 10e30
    p2 = rd.continue_line(theta, sad, x_min, x_max)
    p3 = at.energy_limit_factor(E, theta, forward)
    p4 = at.energy_distribution(E)
    return p1 * p2 * p3 * p4