tfb_cholesky_outer_product | R Documentation |
g(X) = X @ X.T
where X
is lower-triangular, positive-diagonal matrixNote: the upper-triangular part of X is ignored (whether or not its zero).
tfb_cholesky_outer_product( validate_args = FALSE, name = "cholesky_outer_product" )
validate_args |
Logical, default FALSE. Whether to validate input with asserts. If validate_args is FALSE, and the inputs are invalid, correct behavior is not guaranteed. |
name |
name prefixed to Ops created by this class. |
The surjectivity of g as a map from the set of n x n positive-diagonal
lower-triangular matrices to the set of SPD matrices follows immediately from
executing the Cholesky factorization algorithm on an SPD matrix A
to produce a
positive-diagonal lower-triangular matrix L
such that A = L @ L.T
.
To prove the injectivity of g, suppose that L_1
and L_2
are lower-triangular
with positive diagonals and satisfy A = L_1 @ L_1.T = L_2 @ L_2.T
. Then
inv(L_1) @ A @ inv(L_1).T = [inv(L_1) @ L_2] @ [inv(L_1) @ L_2].T = I
.
Setting L_3 := inv(L_1) @ L_2
, that L_3
is a positive-diagonal
lower-triangular matrix follows from inv(L_1)
being positive-diagonal
lower-triangular (which follows from the diagonal of a triangular matrix being
its spectrum), and that the product of two positive-diagonal lower-triangular
matrices is another positive-diagonal lower-triangular matrix.
A simple inductive argument (proceeding one column of L_3
at a time) shows
that, if I = L_3 @ L_3.T
, with L_3
being lower-triangular with positive-
diagonal, then L_3 = I
. Thus, L_1 = L_2
, proving injectivity of g.
a bijector instance.
For usage examples see tfb_forward()
, tfb_inverse()
, tfb_inverse_log_det_jacobian()
.
Other bijectors:
tfb_absolute_value()
,
tfb_affine_linear_operator()
,
tfb_affine_scalar()
,
tfb_affine()
,
tfb_ascending()
,
tfb_batch_normalization()
,
tfb_blockwise()
,
tfb_chain()
,
tfb_cholesky_to_inv_cholesky()
,
tfb_correlation_cholesky()
,
tfb_cumsum()
,
tfb_discrete_cosine_transform()
,
tfb_expm1()
,
tfb_exp()
,
tfb_ffjord()
,
tfb_fill_scale_tri_l()
,
tfb_fill_triangular()
,
tfb_glow()
,
tfb_gompertz_cdf()
,
tfb_gumbel_cdf()
,
tfb_gumbel()
,
tfb_identity()
,
tfb_inline()
,
tfb_invert()
,
tfb_iterated_sigmoid_centered()
,
tfb_kumaraswamy_cdf()
,
tfb_kumaraswamy()
,
tfb_lambert_w_tail()
,
tfb_masked_autoregressive_default_template()
,
tfb_masked_autoregressive_flow()
,
tfb_masked_dense()
,
tfb_matrix_inverse_tri_l()
,
tfb_matvec_lu()
,
tfb_normal_cdf()
,
tfb_ordered()
,
tfb_pad()
,
tfb_permute()
,
tfb_power_transform()
,
tfb_rational_quadratic_spline()
,
tfb_rayleigh_cdf()
,
tfb_real_nvp_default_template()
,
tfb_real_nvp()
,
tfb_reciprocal()
,
tfb_reshape()
,
tfb_scale_matvec_diag()
,
tfb_scale_matvec_linear_operator()
,
tfb_scale_matvec_lu()
,
tfb_scale_matvec_tri_l()
,
tfb_scale_tri_l()
,
tfb_scale()
,
tfb_shifted_gompertz_cdf()
,
tfb_shift()
,
tfb_sigmoid()
,
tfb_sinh_arcsinh()
,
tfb_sinh()
,
tfb_softmax_centered()
,
tfb_softplus()
,
tfb_softsign()
,
tfb_split()
,
tfb_square()
,
tfb_tanh()
,
tfb_transform_diagonal()
,
tfb_transpose()
,
tfb_weibull_cdf()
,
tfb_weibull()
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