Exemplo n.º 1
0
 def __init__(
     self,
     Theta,
     e7=e7,
     verbose=False,
     check_gaugeability=True,
     gaugeability_atol=1e-8,
     # Either `None`, or ('SUSY', None),
     # or ('M2G', {[8]-sequence of masses}).
     stationarity_tweak=None):
     super().__init__(e7.t56r, verbose=verbose)
     if check_gaugeability:
         if get_gaugeability_condition_violations(Theta,
                                                  e7=e7,
                                                  atol=gaugeability_atol):
             raise ValueError('Non-gaugeable Theta-tensor provided.')
     self._stationarity_tweak = stationarity_tweak
     self._opt_tc_stationarity_tweak = (
         None if stationarity_tweak is None or stationarity_tweak[1] is None
         else mu.tff64(stationarity_tweak[1]))
     self._tc_X = tc_X = mu.tff64(get_X(Theta, e7=e7))
     self._tc_XX = tf.einsum('MNQ,PQN->MP', tc_X, tc_X)
     self._tc_e7_S_rc = tf.constant(e7.S_rc, dtype=tf.complex128)
     self._tc_1j = mu.tfc128(0, 1)
     self._tc_28_8_8 = tf.constant(algebra.g.su8.m_28_8_8,
                                   dtype=tf.complex128)
     self._tc_56_888 = tf.constant(algebra.g.su8.m_56_8_8_8,
                                   dtype=tf.complex128)
     self._tc_eps_56_56_8_8 = tf.constant(algebra.g.su8.eps_56_56_8_8,
                                          dtype=tf.complex128)
     self._tc_omega = tf.constant(e7.omega, dtype=tf.complex128)
Exemplo n.º 2
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def align_proj133o(proj133o_target, proj133o, e7=e7, debug=True):
    """Finds an E7-split-133o-rotation that aligns two 133o-projectors."""
    # 'Split rotation' here means that on an ^a-index, we first apply a
    # 'compact SU(8)' and then a 'noncompact E7' rotation.
    tc_fo_abC = mu.tff64(e7.fo_abC)
    tc_proj133o_target = mu.tff64(proj133o_target)
    tc_proj133o = mu.tff64(proj133o)

    def tf_rotated(t_133o):
        t_gen_noncompact = tf.einsum('abC,a->Cb', tc_fo_abC[:70, :, :],
                                     t_133o[:70])
        t_gen_compact = tf.einsum('abC,a->Cb', tc_fo_abC[70:, :, :],
                                  t_133o[70:])
        t_rot = (
            tf.linalg.expm(t_gen_noncompact) @ tf.linalg.expm(t_gen_compact))
        t_rot_inv = (
            tf.linalg.expm(-t_gen_compact) @ tf.linalg.expm(-t_gen_noncompact))
        return t_rot @ tc_proj133o @ t_rot_inv

    def tf_rotation_loss(t_133o):
        t_rotated = tf_rotated(t_133o)
        t_loss = tf.math.reduce_sum(
            tf.math.square(t_rotated - tc_proj133o_target))
        if debug:
            print(f'Loss: {t_loss.numpy():.6g}')
        return t_loss

    opt_val, opt_rot = mu.tf_minimize_v2(
        tf_rotation_loss,
        mu.rng(0).normal(size=133, scale=1e-3))
    # Note that output-index of the projector is ^a. To this, we apply NC @ C.
    return opt_val, opt_rot, tf_rotated(mu.tff64(opt_rot)).numpy()
Exemplo n.º 3
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 def get_subspace_aligner(self, target_subspace_an, rcond=1e-10):
   """Returns a closure that aligns a scalar vector with a target space."""
   target_subspace_an = numpy.asarray(target_subspace_an)
   if target_subspace_an.shape[0] != 70 or len(target_subspace_an.shape) != 2:
     raise ValueError(
         'Target subspace must be a [70, D]-array, '
         f'shape is: {target_subspace_an.shape}')
   tc_f_abC = mu.tff64(self.e7.f_abC)
   v70o_target_subspace_an = mu.nsum(
       'an,Aa->An', target_subspace_an, self.e7.v70o_from_v70)
   svd_u, svd_s, svd_vh = numpy.linalg.svd(v70o_target_subspace_an,
                                           full_matrices=False)
   del svd_vh  # Unused, named for documentation purposes only.
   v70o_target_subspace_an_basis = svd_u[:, svd_s > rcond]
   tc_v70o_proj_complement = mu.tff64(
       numpy.eye(70) -
       v70o_target_subspace_an_basis.dot(v70o_target_subspace_an_basis.T))
   tc_v70o_from_v70 = mu.tff64(self.e7.v70o_from_v70)
   #
   def f_do_align(v70, **kwargs):
     tc_v70 = mu.tff64(v70)
     def tf_loss(t_rot_params):
       t_gen_so8 = tf.einsum('abC,a->Cb', tc_f_abC[-28:, :70, :70],
                             t_rot_params)
       t_rot_so8 = tf.linalg.expm(t_gen_so8)
       t_rotated = tf.einsum('ab,b->a', t_rot_so8, tc_v70)
       t_deviation = tf.einsum(
           'a,Aa,BA->B', t_rotated, tc_v70o_from_v70, tc_v70o_proj_complement)
       return tf.reduce_sum(tf.math.square(t_deviation))
     return mu.tf_minimize_v2(tf_loss, v70, **kwargs)
   #
   return f_do_align
Exemplo n.º 4
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def align_thetas(theta_to_align,
                 thetas_target,
                 e7=e7,
                 debug=True,
                 maxiter=10**4,
                 x0_hint=None,
                 strategy=(('BFGS', None), ),
                 seed=11):
    """Aligns a linear combination of thetas_input with thetas_target."""
    # thetas_target.shape == (num_thetas, 56, 133).
    t0 = t_now = time.time()
    num_thetas = thetas_target.shape[0]
    tf_turners = tf_e7_turners_56_133o(e7=e7)
    # 'Split rotation' here means that on an ^a-index, we first apply a
    # 'compact SU(8)' and then a 'noncompact E7' rotation.
    theta_to_align_56x133o = mu.nsum('Ma,ca->Mc', theta_to_align,
                                     e7.v133o_from_v133)
    tc_theta_to_align_56x133o = mu.tff64(theta_to_align_56x133o)
    thetas_target_56x133o = mu.nsum('nMa,ca->nMc', thetas_target,
                                    e7.v133o_from_v133)
    tc_thetas_target_56x133o = mu.tff64(thetas_target_56x133o)

    def tf_rotated(t_133o):
        t_rot_133o, t_rot_56 = tf_turners(t_133o)
        return tf.einsum('Ma,ba,MN->Nb', tc_theta_to_align_56x133o, t_rot_133o,
                         t_rot_56)

    def tf_rotation_loss(t_133ox):
        nonlocal t_now
        t_rotated = tf_rotated(t_133ox[:133])
        t_target = mu.nsum('nMa,n->Ma', tc_thetas_target_56x133o,
                           t_133ox[133:])
        t_loss = tf.math.reduce_sum(tf.math.square(t_rotated - t_target))
        if debug:
            t_next = time.time()
            print(f'T={t_next - t0:8.3f} sec (+{t_next - t_now:8.3f} sec) '
                  f'Loss: {t_loss.numpy():.12g}')
            t_now = t_next
        return t_loss

    if x0_hint is not None:
        x0 = numpy.asarray(x0_hint)
    else:
        x0 = (mu.rng(seed).normal(size=133, scale=0.05).tolist() +
              mu.rng(seed + 1).normal(size=num_thetas, scale=0.25).tolist())
    opt_val, opt_133ox = mu.tf_minimize_v2(tf_rotation_loss,
                                           x0,
                                           strategy=strategy,
                                           default_maxiter=maxiter,
                                           default_gtol=1e-14)
    # Note that output-index of the projector is ^a.
    # To this, we apply NC @ C.
    return (opt_val, opt_133ox,
            numpy.concatenate(
                [e7.v133_from_v133o.dot(opt_133ox[:133]), opt_133ox[133:]],
                axis=0),
            mu.nsum('Ma,ba->Mb',
                    tf_rotated(mu.tff64(opt_133ox[:133])).numpy(),
                    e7.v133_from_v133o))
Exemplo n.º 5
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 def _canonicalize_equilibrium_sc(self, v70, diagonalize_8x8s=True,
                                  rng=None, verbose=True):
   """Simplifies a location on the scalar manifold by rotation."""
   if rng is None:
     rng = numpy.random.RandomState()
   m8x8s = mu.nsum('Aij,A->ij', self.e7.su8.m_35_8_8.real, v70[:35])
   m8x8c = mu.nsum('Aij,A->ij', self.e7.su8.m_35_8_8.real, v70[35:])
   rot = self.e7.spin8.get_diagonalizing_rotation(
       m8x8s if diagonalize_8x8s else m8x8c)
   decomposed_rot = mu.product_decompose_rotation(rot)
   resynthesized_rot = mu.resynthesize_rotation_for_rep(
       8, 8, decomposed_rot, 'ab,->ab', numpy.ones([]))
   if not numpy.allclose(rot, resynthesized_rot, rtol=1e-3, atol=1e-5):
     raise ValueError(
         'Resynthesized rotation does not match original rotation.')
   generator_mapping_spec = 'sS,sScC->cC' if diagonalize_8x8s else 'cC,sScC->sS'
   rep_action = 0.25 * self.e7.spin8.gamma_sscc
   rot_other_rep = mu.resynthesize_rotation_for_rep(
       8, 8, decomposed_rot, generator_mapping_spec, rep_action)
   (rot_s, rot_c) = ((rot, rot_other_rep) if diagonalize_8x8s
                     else (rot_other_rep, rot))
   canon_m8x8s = rot_s.T @ m8x8s @ rot_s
   canon_m8x8c = rot_c.T @ m8x8c @ rot_c
   if diagonalize_8x8s:
     gens_postdiag = mu.get_generators_for_post_diagonalization_reduction(
         numpy.diag(canon_m8x8s), 'gsS,sScC->gcC', self.e7.spin8.gamma_sscc)
   else:
     gens_postdiag = mu.get_generators_for_post_diagonalization_reduction(
         numpy.diag(canon_m8x8c), 'gcC,sScC->gsS', self.e7.spin8.gamma_sscc)
   tc_rot_gens = mu.tff64(gens_postdiag)
   tc_8x8s = mu.tff64(canon_m8x8s)
   tc_8x8c = mu.tff64(canon_m8x8c)
   @tf.function
   def tf_rotated_8x8(t_rot_params):
     t_rot = mu.tf_expm(
         tf.einsum('gab,g->ab', tc_rot_gens, t_rot_params))
     if diagonalize_8x8s:
       tc_rotated_8x8 = tf.linalg.matmul(
           t_rot @ tc_8x8c, t_rot, transpose_b=True)
     else:
       tc_rotated_8x8 = tf.linalg.matmul(
           t_rot @ tc_8x8s, t_rot, transpose_b=True)
     return tc_rotated_8x8
   @tf.function
   def tf_loss(t_rot_params):
     t_8x8 = tf_rotated_8x8(t_rot_params)
     ret = tf.reduce_sum(tf.abs(t_8x8))
     return ret
   if gens_postdiag.shape[0] == 0:
     return self.e7.v70_from_35s35c(canon_m8x8s, canon_m8x8c)
   _, opt_rot_params = mu.tf_minimize_v2(
       tf_loss,
       rng.normal(scale=1.0, size=gens_postdiag.shape[0]),
       default_gtol=1e-14)
   opt_8x8 = tf_rotated_8x8(mu.tff64(opt_rot_params)).numpy()
   if diagonalize_8x8s:
     return self.e7.v70_from_35s35c(canon_m8x8s, opt_8x8)
   else:
     return self.e7.v70_from_35s35c(opt_8x8, canon_m8x8c)
Exemplo n.º 6
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 def tf_sugra_tensors_from_vielbein(self, t_vielbein, t_omega=None):
   """See base class."""
   t_T = self.tf_T(t_vielbein, t_omega=t_omega)
   t_A1, t_A2, _ = self.tf_A123(t_T, want_A3=False)
   t_potential_A1 = mu.tff64(-3 / 4) * tf.math.real(
       tf.einsum('ij,ij->', t_A1, tf.math.conj(t_A1)))
   t_potential_A2 = mu.tff64(1 / 24) * tf.math.real(
       tf.einsum('ijkl,ijkl->', t_A2, tf.math.conj(t_A2)))
   t_potential = t_potential_A1 + t_potential_A2
   return t_potential, t_T, t_A1, t_A2
Exemplo n.º 7
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 def tf_stationarity_internal(self, t_potential, t_grad_potential,
                              t_vielbein):
     """Computes the stationarity-violation."""
     t_stat = super().tf_stationarity_internal(t_potential,
                                               t_grad_potential, t_vielbein)
     if self._stationarity_tweak is None:
         return tf.math.asinh(t_stat)  # Squashed.
     else:
         t_A1, *_ = self.tf_A123(self.tf_T(t_vielbein),
                                 want_A1=True,
                                 want_A2=False,
                                 want_A3=False)
         t_m2grav = self.tf_gravitino_masses(t_A1, t_potential)
         if self._stationarity_tweak[0] == 'SUSY':
             t_lightest_gravitino_mass = t_m2grav[-1]
             t_ret = t_stat * tf.clip_by_value(t_lightest_gravitino_mass,
                                               1.0, 5.0)
             return tf.math.asinh(t_ret)  # Double-squash
         elif self._stationarity_tweak[0] == 'M2G':
             t_spectrum_mismatch = tf.math.reduce_sum(
                 tf.math.square(t_m2grav - self._stationarity_tweak[1]))
             return (tf.math.asinh(t_stat) +
                     tf.math.asinh(t_spectrum_mismatch) * mu.tff64(0.1))
         else:
             raise ValueError('Unknown stationarity-tweak.')
Exemplo n.º 8
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 def tf_sugra_tensors_from_vielbein(self, t_V):
     """See base class."""
     # We also need the inverse Vielbein.
     # Here, we make use of the inverse of a symplectic matrix
     #   [[A, B], [C, D]]
     # being given by:
     #   [[D.T, -B.T], [-C.T, A.T]].
     t_Vi = tf.reshape(
         tf.stack([
             tf.stack([
                 tf.transpose(t_V[28:, 28:]), -tf.transpose(t_V[:28, 28:])
             ],
                      axis=1),
             tf.stack([
                 -tf.transpose(t_V[28:, :28]),
                 tf.transpose(t_V[:28, :28])
             ],
                      axis=1)
         ],
                  axis=0), (56, 56))
     t_M = tf.einsum('RX,SX->RS', t_V, t_V)
     t_Minv = tf.einsum('XR,XS->RS', t_Vi, t_Vi)
     # Potential (2.9) in arXiv:1112.3345 - also, (4.49) in arXiv:0705.2101.
     t_potential = mu.tff64(1 / 168.0) * (tf.einsum(
         'mnr,mM,nN,rR,MNR->', self._tc_X, t_Minv, t_Minv, t_M,
         self._tc_X) + 7 * tf.einsum('MP,MP->', self._tc_XX, t_Minv))
     return (t_potential, )  # 1-tuple.
Exemplo n.º 9
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def tf_dwn_stationarity_vec(t_A1, t_A2):
    """Computes stationarity-violation 70-vector 'in the local frame'."""
    # Formula:
    # arXiv: https://arxiv.org/pdf/1302.6219.pdf, formula (3.2);
    # originally: https://inspirehep.net/literature/191530
    # (2.20) - (2.22).
    _m_8888sd_35ortho, _m_8888asd_35ortho = _get_35sd_asd_bases()
    t_x0 = (tf.einsum('mi,mjkl->ijkl', t_A1, t_A2) +
            mu.tfc128(-0.75, 0.0) * tf.einsum('mnij,nklm->ijkl', t_A2, t_A2))
    t_x0_real = tf.math.real(t_x0)
    t_x0_imag = tf.math.imag(t_x0)
    # The self-dual part must be zero.
    t_x0_re_sd = tf.einsum('ijkl,ijklX->X', t_x0_real,
                           mu.tff64(_m_8888sd_35ortho))
    t_x0_im_asd = tf.einsum('ijkl,ijklX->X', t_x0_imag,
                            mu.tff64(_m_8888asd_35ortho))
    return tf.concat([t_x0_re_sd, t_x0_im_asd], axis=0)
Exemplo n.º 10
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 def test_known_so8c_solutions(self):
   """Asserts numpy stationarity of the known SO(8)c omega=pi/8 solutions."""
   tc_omega = mu.tff64(numpy.pi / 8)
   for row in mu.csv_numdata('dim4/so8/equilibria/SO8C_PI8_SOLUTIONS.csv'):
     table_potential = row[0]
     potential, stationarity = SUGRA.potential_and_stationarity(
         row[2:], t_omega=tc_omega)
     self.assertTrue(0.0 <= stationarity <= 1e-7)
     self.assertTrue(numpy.isclose(potential, table_potential, atol=1e-8))
Exemplo n.º 11
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 def holomorphic_w_sugra(zs):
   gs = mu.undiskify(zs) * 0.25
   v70 = mu.nsum('zna,zn->a',
                 algebra.g.e7.sl2x7[:2, :, :70],
                 numpy.stack([gs.real, gs.imag], axis=0))
   A1 = SUGRA.tf_ext_sugra_tensors(mu.tff64(v70),
                                   with_stationarity=False)[2].numpy()
   kaehler_factor = numpy.sqrt((1 - zs * zs.conjugate()).prod())
   return a123.superpotential(A1, direction_A1) * kaehler_factor
Exemplo n.º 12
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 def test_one_nontrivial_solution(self):
   """Asserts numpy stationarity of a nontrivial solution."""
   t_v70 = mu.tff64(_EXAMPLE_SOLUTION)
   tensors_stat = SUGRA.tf_ext_sugra_tensors(t_v70, with_stationarity=True)
   tensors_nostat = SUGRA.tf_ext_sugra_tensors(t_v70, with_stationarity=False)
   self.assertTrue(0 <= tensors_stat[-1].numpy() <= 1e-3)
   self.assertTrue(-8.473 <= tensors_stat[0].numpy() <= -8.472)
   self.assertTrue(numpy.isnan(tensors_nostat[-1].numpy()))
   self.assertTrue(numpy.allclose(tensors_stat[0].numpy(),
                                  tensors_nostat[0].numpy()))
Exemplo n.º 13
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def tf_e7_turners_56_133o(e7=e7):
    """Returns closure that maps 70+63 e7-rotation to _56 and ^133o matrices."""
    # This is a somewhat technical helper function which however
    # is useful to have in quite a few places.
    tc_fo_abC = mu.tff64(e7.fo_abC)
    tc_to56r = mu.tff64(mu.nsum('aMN,ac->cMN', e7.t56r, e7.v133_from_v133o))

    def tf_turners(t_133o, order133_c_first=True):
        """Returns 133o x 133o and 56 x 56 rotation matrices.

    Args:
      t_133o: numpy.ndarray, rotation-parameters in the
        133o-irrep of e7 from which we build two rotations
        (per Theta-index, so four in total), one for the
        compact and one for the noncompact part of the algebra.
      order133_c_first: If true, the 133o-rotation is built
        by first performing the compact, then the noncompact
        rotation. (Useful for taking inverses.)

    Returns:
      A pair `(t_rot_133o, t_rot_56)` of a [133, 133]-float64-tf.Tensor
      `t_rot133o` rotating the 133o-index on Theta and a
      [56, 56]-float64-tf.Tensor rotating the 56-index on Theta.
    """
        t_70 = t_133o[:70]
        t_63 = t_133o[70:]
        t_rot_nc133o = tf.linalg.expm(
            tf.einsum('abC,a->Cb', tc_fo_abC[:70], t_70))
        t_rot_c133o = tf.linalg.expm(
            tf.einsum('abC,a->Cb', tc_fo_abC[70:], t_63))
        t_rot_nc56 = tf.linalg.expm(
            tf.einsum('aMN,a->NM', tc_to56r[:70], -t_70))
        t_rot_c56 = tf.linalg.expm(tf.einsum('aMN,a->NM', tc_to56r[70:],
                                             -t_63))
        if order133_c_first:
            t_rot_133o = t_rot_nc133o @ t_rot_c133o
            t_rot_56 = t_rot_c56 @ t_rot_nc56
        else:
            t_rot_133o = t_rot_nc133o @ t_rot_c133o
            t_rot_56 = t_rot_c56 @ t_rot_nc56
        return t_rot_133o, t_rot_56

    return tf_turners
Exemplo n.º 14
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 def test_origin_so8_solution(self):
   """Asserts properties of the solution at the origin."""
   t_v70 = mu.tff64([0] * 70)
   pot, tt, a1, a2, stat = [x.numpy()
                            for x in SUGRA.tf_ext_sugra_tensors(t_v70)]
   self.assertTrue(numpy.allclose(-6.0, pot))
   self.assertTrue(0 <= stat <= 1e-20)
   self.assertTrue(numpy.allclose(numpy.eye(8), a1))
   self.assertTrue(numpy.allclose(0, a2))
   tt_entries = sorted(collections.Counter(tt.ravel()).items())
   self.assertEqual([(-0.75, 56), (0, 3984), (0.75, 56)], tt_entries)
Exemplo n.º 15
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 def f_do_align(v70, **kwargs):
   tc_v70 = mu.tff64(v70)
   def tf_loss(t_rot_params):
     t_gen_so8 = tf.einsum('abC,a->Cb', tc_f_abC[-28:, :70, :70],
                           t_rot_params)
     t_rot_so8 = tf.linalg.expm(t_gen_so8)
     t_rotated = tf.einsum('ab,b->a', t_rot_so8, tc_v70)
     t_deviation = tf.einsum(
         'a,Aa,BA->B', t_rotated, tc_v70o_from_v70, tc_v70o_proj_complement)
     return tf.reduce_sum(tf.math.square(t_deviation))
   return mu.tf_minimize_v2(tf_loss, v70, **kwargs)
Exemplo n.º 16
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 def tf_T(self, t_vielbein, t_omega=None):
   """Computes the SO(8) T-tensor."""
   t_omega = mu.tff64(0.0) if t_omega is None else t_omega
   t_u_ijIJ = self._expand_ijkl(t_vielbein[:28, :28])
   t_u_klKL = tf.math.conj(t_u_ijIJ)
   t_v_ijKL = self._expand_ijkl(t_vielbein[:28, 28:])
   t_v_klIJ = tf.math.conj(t_v_ijKL)
   t_cw = tf.math.cos(t_omega)
   t_sw = tf.math.sin(t_omega)
   tc_exp_w = tf.complex(t_cw, t_sw)
   tc_exp_nw = tf.complex(t_cw, -t_sw)
   t_uv = tc_exp_nw * t_u_klKL + tc_exp_w * t_v_klIJ
   t_uuvv = (
       tf.einsum('lmJK,kmKI->lkIJ', t_u_ijIJ, t_u_klKL) -
       tf.einsum('lmJK,kmKI->lkIJ', t_v_ijKL, t_v_klIJ))
   return tf.einsum('ijIJ,lkIJ->lkij', t_uv, t_uuvv)
Exemplo n.º 17
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def refine_omega_zs(omega,
                    zs,
                    verbosity='SF',
                    sugra=None,
                    e7=None,
                    debug=False):
    """Refines z-coordinate vectors to low stationarity-violation."""
    if e7 is None:
        e7 = algebra.g.e7
    if sugra is None:
        sugra = analysis.SO8_SUGRA(e7=e7)
    cs = numpy.array(
        # Factor 0.25 is due to normalization of SL(2)-generators.
        [0.25 * mu.undiskify(z / max(1,
                                     abs(z) + 1e-5)) for z in zs])
    current_opt_stat = 1.0
    current_opt_pos = numpy.concatenate([cs.real, cs.imag], axis=0)
    # It is very important that we do get a good-quality equilibrium here.
    # If we do not, this would seriously mess up convergence acceleration
    # as we use it to distill out the boundary-tensor.
    while current_opt_stat > 1e-12:
        opt = sugra.find_equilibrium(
            current_opt_pos,
            verbosity=verbosity,
            submanifold_embedding=e7.sl2x7[:2, :, :70].reshape(14, 70),
            t_omega=mu.tff64(omega),
            minimize_kwargs=dict(default_gtol=1e-14, default_maxiter=10**5))
        current_opt_pot, current_opt_stat, current_opt_pos = opt
    if debug:
        print(f'Debug: refined opt_pot={current_opt_pot}, '
              f'opt_stat={current_opt_stat}')
    refined_zs = numpy.array([
        mu.diskify(4 * z)
        for z in current_opt_pos[:7] + 1j * current_opt_pos[7:]
    ])
    return omega, current_opt_pot, current_opt_stat, refined_zs
Exemplo n.º 18
0
  ds_step = 0.003
  scan_boundary_gauging_num_samples = 50
  scan_file = os.path.join(target_dir, 'u4xr12_equilibria.csv')
  analyzed_file = os.path.join(target_dir, 'u4xr12_equilibria_analyzed.pytxt')
  os.makedirs(target_dir, exist_ok=True)


if mu.arg_enabled(__name__, 'compute_trajectory'):
  print('# Computing SO(3) N=1 trajectory on SL2x7...')
  v14 = analyze_sl2x7.v14_from_7z(analyze_sl2x7.get_7z_from_bfp_z123(
      # Numbers match Eq. (4.31) in BFP, https://arxiv.org/abs/1909.10969
      (0.1696360+0.1415740j, 0.4833214+0.3864058j, -0.3162021-0.5162839j)))
  v70_so3n1 = subspace_an.dot(v14)
  # Check that we do have the correct equilibrium.
  pot, stat = sugra.potential_and_stationarity(v70_so3n1,
                                               t_omega=mu.tff64(0.0))
  assert abs(-13.84096 - pot) < 1e-4 and stat < 1e-8
  dyonic.analyze_omega_deformation(
      mu.home_relative(target_dir),
      v70_so3n1,
      ds=ds_step)
  glob_pos, glob_neg = (
      os.path.join(target_dir, f'S1384096/omega_0.0000_{tag}_*.log')
      for tag in ('pos', 'neg'))
  tdata = dyonic.collect_trajectory_logs(glob_pos, glob_neg)
  numpy.save(trajectory_npy_filename, tdata)


if mu.arg_enabled(__name__, 'extrapolate_and_plot'):
  print('# Extrapolating trajectory and plotting...')
  tdata = numpy.load(trajectory_npy_filename)
Exemplo n.º 19
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 def pot_stat_7z(zs, omega):
     return sugra.potential_and_stationarity(v70_from_7z(zs, e7=sugra.e7),
                                             t_omega=mu.tff64(omega))
Exemplo n.º 20
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def tf_dwn_stationarity(t_A1, t_A2):
    """Computes stationarity-violation 'in the local frame'."""
    return (tf.math.reduce_sum(
        tf.math.square(tf_dwn_stationarity_vec(t_A1, t_A2))) / mu.tff64(48.0))