Пример #1
0
def compare(hbar=1, k0=1, m=1, r0=1, V0=-1, deg=40, c=10, maxl=10):
    an.setparams(hbar, k0, m)
    sc.setparams(hbar, k0, m)
    sc.setquadparams(deg, c)
    print(len(sc.KK))
    b = an.box(r0, V0)
    V = b.V

    f = sc.amplitude_f(V, maxl, isbox=False, r0=0)
    fan = b.amplitude_f(maxl)

    theta = np.linspace(0, np.pi, 10000)
    plt.plot(theta, sc.modsq(f(theta)), theta, sc.modsq(fan(theta)))
    print('sc: {}'.format(sc.stot(f) - np.pi * 4 / k0 * np.imag(f(0))))
    print('an: {}'.format(sc.stot(fan) - np.pi * 4 / k0 * np.imag(fan(0))))
    print('----fl----')
    for l in range(maxl + 1):
        print('l={}'.format(l))
        print('sc: {}'.format(sc.tmp_fl[l]))
        print('an: {}'.format(b.f[l]))
        print()
    plt.xlabel(
        'hbar={}, k0={}, m={}, r0={}, V0={}, maxl={}, deg_legendre={}'.format(
            hbar, k0, m, r0, V0, maxl, deg))
    plt.show()
Пример #2
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def testeq():
    b = an.box(1, -1)
    V = b.V

    Tconj = sc.T_conj(V, 10)
    N = sc.DEG + 1
    #L=0

    flag = True
    for L in range(0, 11):
        V0 = sc.V_l(V, L)
        for J in range(0, 41):
            print('J={}'.format(J))
            #print(Tconj[0][J])

            S = 0
            for i in range(1, N):
                S += W[i - 1] * (KK[i]**2 * V0[J][i] * Tconj[L][i] -
                                 KK[0]**2 * V0[J][0] * Tconj[L][0]) / (
                                     KK[0]**2 - KK[i]**2)

            TTT = V0[J][0] + 4 * m / (np.pi *
                                      hbar**2) * S - 1j * 2 * m * k0 / (
                                          hbar**2) * V0[J][0] * Tconj[L][0]

            f = (abs((TTT - Tconj[L][J]) / TTT) < 1e-13)
            flag = f
            print(f)

    print('overall {}'.format(flag))
Пример #3
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def kkk():
    r = np.linspace(0, 10, 10000)
    th = np.linspace(0, np.pi, 10000)
    V = col.box(-1, 5)
    plt.plot(r, V(r))
    plt.show()

    K_SAMPLE = [0.01, 0.1, 0.5, 1, 10, 20, 50, 100]

    for k0 in K_SAMPLE:
        g = an.general(1, k0, 1, V, 5)
        fg = g.amplitude_f(10)

        an.k0 = k0
        b = an.box(5, -1)
        fan = b.amplitude_f(10)

        sc.setquadparams(deg=40)
        sc.setparams(k01=k0)
        f = sc.amplitude_f(V, 10, isbox=True, r0=5)

        q = utils.maxerror(th, fg, f)
        #print('maxereror: {}'.format(q))
        plt.plot(th, fg(th), th, f(th), th, fan(th))
        plt.xlabel(sc.summary())
        plt.show()
Пример #4
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def a1():
    r = np.linspace(0, 10, 10000)
    th = np.linspace(0, np.pi, 10000)

    V = col.box(-1, 5)
    plt.plot(r, V(r))
    plt.show()

    g = an.general(1, 50, 1, V, 5)
    fg = g.amplitude_f(10)

    an.k0 = 50
    b = an.box(5, -1)
    fan = b.amplitude_f(10)

    sc.setquadparams(deg=80)
    sc.setparams(k01=50)
    f = sc.amplitude_f(V, 10)

    plt.plot(th, fg(th), th, f(th), th, fan(th))
    plt.xlabel(sc.summary())
    plt.show()
Пример #5
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def sc_l_deg(hbar=1,
             k0=1,
             m=1,
             V=V_sample,
             degs=[30, 40, 50, 60, 70],
             c=10,
             maxl=10):
    an.setparams(hbar, k0, m)
    sc.setparams(hbar, k0, m)
    theta = np.linspace(0, np.pi, 10000)

    b = an.box(5, -1)

    for deg in degs:
        sc.setquadparams(deg, c)
        f = sc.amplitude_f(V, maxl, isbox=True, r0=5)
        plt.plot(theta, sc.modsq(f(theta)), label=str(deg))

    fan = b.amplitude_f(maxl)
    plt.plot(theta, sc.modsq(fan(theta)), label='partial wave')
    plt.legend()
    plt.xlabel('hbar={}, k0={}, m={}, V={}, maxl={}, degs={}'.format(
        hbar, k0, m, 'box(5, -1)', maxl, degs))
    plt.show()
Пример #6
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def sc_l_maxl(hbar=1,
              k0=1,
              m=1,
              V=V_sample,
              deg=40,
              c=10,
              maxls=[5, 10, 20, 30, 40]):
    an.setparams(hbar, k0, m)
    sc.setparams(hbar, k0, m)
    theta = np.linspace(0, np.pi, 10000)

    b = an.box(5, -1)

    for maxl in maxls:
        #sc.setquadparams(deg, c)
        f = sc.amplitude_f(V, maxl, isbox=True, r0=5)
        plt.plot(theta, sc.modsq(f(theta)), label=str(maxl))

    fan = b.amplitude_f(maxl)
    plt.plot(theta, sc.modsq(fan(theta)), label='partial wave')
    plt.legend()
    plt.xlabel('hbar={}, k0={}, m={}, V={}, maxl={}, deg={}'.format(
        hbar, k0, m, 'box(5, -1)', maxls, deg))
    plt.show()