コード例 #1
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def test_optimize_LF(M, C=3):
    import example_speaker_arrays as esa
    h_order, v_order, sh_l, sh_m = pc.ambisonic_channels(C)
    S = esa.nando_dome(False)

    M_opt, ret = optimize_LF(M, S.u.T, sh_l, sh_m)

    return M_opt, ret
コード例 #2
0
def optimize_dome_LF(M_hf,
                     S,
                     ambisonic_order=3,
                     el_lim=-π/8):

    order_h, order_v, sh_l, sh_m, id_string = pc.ambisonic_channels(ambisonic_order)

    # the test directions
    T = sg.t_design5200()
    cap = sg.spherical_cap(T.u, (0, 0, 1), 5*np.pi/6)[0]
    W = np.where(cap, 0.1, 1)

    M_lf, res = optimize_LF(M_hf, S.u.T, sh_l, sh_m, W)

    return M_lf, res
コード例 #3
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def unit_test(C):
    """Run unit test for the optimizer with uniform array."""
    #
    #sh_l, sh_m = zip(*rsh.lm_generator(ambisonic_order))
    h_order, v_order, sh_l, sh_m = pc.ambisonic_channels(C)
    # make a  decoder matrix for the 240 speaker t-design via pseudoinverse
    S240 = sg.t_design240()
    Su = S240.u

    # shelf filter gains for max_rE
    gamma = shelf.gamma(sh_l,
                        decoder_type='max_rE',
                        decoder_3d=True,
                        return_matrix=True)

    # since this is a spherical design, all three methods should yield the
    # same result

    # 1 - inversion
    M240 = bd.inversion(sh_l, sh_m, S240.az, S240.el)

    M240_hf = M240 @ gamma

    lm.plot_performance(M240_hf, Su, sh_l, sh_m, title='Pinv unit test')
    lm.plot_matrix(M240_hf, title='Pinv unit test')

    # 2 - AllRAD
    M240_allrad = bd.allrad(sh_l, sh_m, S240.az, S240.el)
    M240_allrad_hf = M240_allrad @ gamma
    lm.plot_performance(M240_allrad_hf,
                        Su,
                        sh_l,
                        sh_m,
                        title='AllRAD unit test')
    lm.plot_matrix(M240_allrad_hf, title='AllRAD unit test')

    # 3 - NLOpt
    M_opt, res = optimize(None, Su, sh_l, sh_m, E_goal=1, sparseness_penalty=0)
    lm.plot_performance(M_opt, Su, sh_l, sh_m, title='Optimized unit test')
    lm.plot_matrix(M240_allrad, title='Optimized unit test')
    return res
コード例 #4
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def optimize_dome(S,  # the speaker array
                  ambisonic_order=3,
                  el_lim=-π/8,
                  tikhonov_lambda=1e-3,
                  sparseness_penalty=1,
                  do_report=False,
                  rE_goal='auto',
                  eval_order=None,
                  random_start=False
                  ):
    """Test optimizer with CCRMA Stage array."""
    #
    #
    order_h, order_v, sh_l, sh_m, id_string = pc.ambisonic_channels(ambisonic_order)
    order = max(order_h, order_v)  # FIXME
    is_3D = order_v > 0

    if eval_order is None:
        eval_order = ambisonic_order
        eval_order_given = False
    else:
        eval_order_given = True

    eval_order_h, eval_order_v, eval_sh_l, eval_sh_m, eval_id_string = \
        pc.ambisonic_channels(eval_order)

    mask_matrix = pc.mask_matrix(eval_sh_l, eval_sh_m, sh_l, sh_m)
    print(mask_matrix)

    # if True:
    #     S = esa.stage2017() + esa.nadir()#stage()
    #     spkr_array_name = S.name
    # else:
    #     # hack to enter Eric's array
    #     S = emb()
    #     spkr_array_name = 'EMB'

    spkr_array_name = S.name



    print('speaker array = ', spkr_array_name)

    S_u = np.array(sg.sph2cart(S.az, S.el, 1))

    gamma = shelf.gamma(sh_l, decoder_type='max_rE', decoder_3d=is_3D,
                        return_matrix=True)

    figs = []
    if not random_start:
        M_start = 'AllRAD'

        M_allrad = bd.allrad(sh_l, sh_m, S.az, S.el,
                             speaker_is_real=S.is_real)

        # remove imaginary speaker from S_u and Sr
        S_u = S_u[:, S.is_real] #S.Real.values]
        Sr = S[S.is_real] #S.Real.values]

        M_allrad_hf = M_allrad @ gamma

        # performance plots
        plot_title = "AllRAD, "
        if eval_order_given:
            plot_title += f"Design: {id_string}, Test: {eval_id_string}"
        else:
            plot_title += f"Signal set={id_string}"

        figs.append(
            lm.plot_performance(M_allrad_hf, S_u, sh_l, sh_m,
                                mask_matrix = mask_matrix,
                                title=plot_title))

        lm.plot_matrix(M_allrad_hf, title=plot_title)

        print(f"\n\n{plot_title}\nDiffuse field gain of each loudspeaker (dB)")
        for n, g in zip(Sr.ids,
                        10 * np.log10(np.sum(M_allrad ** 2, axis=1))):
            print(f"{n:3}:{g:8.2f} |{'=' * int(60 + g)}")

    else:
        M_start = 'Random'
        # let optimizer dream up a decoder on its own
        M_allrad = None
        # more mess from imaginary speakers
        S_u = S_u[:, S.is_real]
        Sr = S[S.is_real]

    # M_allrad = None

    # Objective for E
    T = sg.t_design5200()
    cap, *_ = sg.spherical_cap(T.u,
                               (0, 0, 1),  # apex
                               π/2 - el_lim)
    E0 = np.where(cap, 1.0, 0.1)  # inside, outside

    # np.array([0.1, 1.0])[cap.astype(np.int8)]

    # Objective for rE order+2 inside the cap, order-2 outside
    rE_goal = np.where(cap,
                       shelf.max_rE_3d(order+2), # inside the cap
                       shelf.max_rE_3d(max(order-2, 1)) # outside the cap
                       )

    #np.array([shelf.max_rE_3d(max(order-2, 1)),
    #                    shelf.max_rE_3d(order+2)])[cap.astype(np.int8)]

    M_opt, res = optimize(M_allrad, S_u, sh_l, sh_m, E_goal=E0,
                          iprint=50, tikhonov_lambda=tikhonov_lambda,
                          sparseness_penalty=sparseness_penalty,
                          rE_goal=rE_goal)

    plot_title = f"Optimized {M_start}, "
    if eval_order_given:
        plot_title += f"Design: {id_string}, Test: {eval_id_string}"
    else:
        plot_title += f"Signal set={id_string}"

    figs.append(
        lm.plot_performance(M_opt, S_u, sh_l, sh_m,
                            mask_matrix = mask_matrix,
                            title=plot_title
                            ))

    lm.plot_matrix(M_opt, title=plot_title)

    with io.StringIO() as f:
        print(f"ambisonic_order = {order}\n" +
              f"el_lim = {el_lim * 180 / π}\n" +
              f"tikhonov_lambda = {tikhonov_lambda}\n" +
              f"sparseness_penalty = {sparseness_penalty}\n",
              file=f)

        off = np.isclose(np.sum(M_opt ** 2, axis=1), 0, rtol=1e-6)  # 60dB down
        print("Using:\n", Sr.ids[~off.copy()], file=f)
        print("Turned off:\n", Sr.ids[off.copy()], file=f)

        print("\n\nDiffuse field gain of each loudspeaker (dB)", file=f)
        for n, g in zip(Sr.ids,
                        10 * np.log10(np.sum(M_opt ** 2, axis=1))):
            print(f"{n:3}:{g:8.2f} |{'=' * int(60 + g)}", file=f)
        report = f.getvalue()
        print(report)

    if do_report:
        reports.html_report(zip(*figs),
                            text=report,
                            directory=spkr_array_name,
                            name=f"{spkr_array_name}-{id_string}")

    return M_opt, dict(M_allrad=M_allrad, off=off, res=res)
コード例 #5
0
import example_speaker_arrays as esa
import localization_models as lm
import program_channels as pc
import basic_decoders as bd
import write_faust_decoder as wfd
import shelf

figs = []

# %%
S = esa.nando_dome(add_imaginary=True)
S_real = esa.nando_dome(add_imaginary=False)


C = pc.ChannelsAmbiX(3, 2)
order_h, order_v, sh_l, sh_m, id_string = pc.ambisonic_channels(C)

# %% example gamma calculations

gamma = shelf.gamma(sh_l, decoder_type='max_rE', decoder_3d=True,
                    return_matrix=False)
print(C.id_string(), 'sh_l =', sh_l, '\n', gamma)

gamma0 = shelf.gamma0(gamma, matching_type='rms')
print(C.id_string(), gamma0)

# for 1H1P gamma0 should be +3 dB (from Gerzon, Practical Periphony)
C_1H1P = pc.ChannelsFuMa(1,1)
sh_l_11 = C_1H1P.sh_l

gamma_11 = shelf.gamma(sh_l_11, decoder_type='max_rE', decoder_3d=True,