Mercurial > hg > octave-nkf
view scripts/sparse/spaugment.m @ 20038:9fc020886ae9
maint: Clean up m-files to follow Octave coding conventions.
Try to trim long lines to < 80 chars.
Use '##' for single line comments.
Use '(...)' around tests for if/elseif/switch/while.
Abut cell indexing operator '{' next to variable.
Abut array indexing operator '(' next to variable.
Use space between negation operator '!' and following expression.
Use two newlines between endfunction and start of %!test or %!demo code.
Remove unnecessary parens grouping between short-circuit operators.
Remove stray extra spaces (typos) between variables and assignment operators.
Remove stray extra spaces from ends of lines.
| author | Rik <rik@octave.org> |
|---|---|
| date | Mon, 23 Feb 2015 14:54:39 -0800 |
| parents | 4197fc428c7d |
| children | df437a52bcaf |
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## Copyright (C) 2008-2015 David Bateman ## ## This file is part of Octave. ## ## Octave is free software; you can redistribute it and/or modify it ## under the terms of the GNU General Public License as published by ## the Free Software Foundation; either version 3 of the License, or (at ## your option) any later version. ## ## Octave is distributed in the hope that it will be useful, but ## WITHOUT ANY WARRANTY; without even the implied warranty of ## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU ## General Public License for more details. ## ## You should have received a copy of the GNU General Public License ## along with Octave; see the file COPYING. If not, see ## <http://www.gnu.org/licenses/>. ## -*- texinfo -*- ## @deftypefn {Function File} {@var{s} =} spaugment (@var{A}, @var{c}) ## Create the augmented matrix of @var{A}. ## ## This is given by ## ## @example ## @group ## [@var{c} * eye(@var{m}, @var{m}), @var{A}; ## @var{A}', zeros(@var{n}, @var{n})] ## @end group ## @end example ## ## @noindent ## This is related to the least squares solution of ## @code{@var{A} \ @var{b}}, by ## ## @example ## @group ## @var{s} * [ @var{r} / @var{c}; x] = [ @var{b}, zeros(@var{n}, columns(@var{b})) ] ## @end group ## @end example ## ## @noindent ## where @var{r} is the residual error ## ## @example ## @var{r} = @var{b} - @var{A} * @var{x} ## @end example ## ## As the matrix @var{s} is symmetric indefinite it can be factorized ## with @code{lu}, and the minimum norm solution can therefore be found ## without the need for a @code{qr} factorization. As the residual ## error will be @code{zeros (@var{m}, @var{m})} for underdetermined ## problems, and example can be ## ## @example ## @group ## m = 11; n = 10; mn = max (m, n); ## A = spdiags ([ones(mn,1), 10*ones(mn,1), -ones(mn,1)], ## [-1, 0, 1], m, n); ## x0 = A \ ones (m,1); ## s = spaugment (A); ## [L, U, P, Q] = lu (s); ## x1 = Q * (U \ (L \ (P * [ones(m,1); zeros(n,1)]))); ## x1 = x1(end - n + 1 : end); ## @end group ## @end example ## ## To find the solution of an overdetermined problem needs an estimate ## of the residual error @var{r} and so it is more complex to formulate ## a minimum norm solution using the @code{spaugment} function. ## ## In general the left division operator is more stable and faster than ## using the @code{spaugment} function. ## @seealso{mldivide} ## @end deftypefn function s = spaugment (A, c) if (nargin < 2) if (issparse (A)) c = max (max (abs (A))) / 1000; else if (ndims (A) != 2) error ("spaugment: expecting 2-dimenisional matrix"); else c = max (abs (A(:))) / 1000; endif endif elseif (! isscalar (c)) error ("spaugment: C must be a scalar"); endif [m, n] = size (A); s = [ c * speye(m, m), A; A', sparse(n, n)]; endfunction %!testif HAVE_UMFPACK %! m = 11; n = 10; mn = max (m ,n); %! A = spdiags ([ones(mn,1), 10*ones(mn,1), -ones(mn,1)],[-1,0,1], m, n); %! x0 = A \ ones (m,1); %! s = spaugment (A); %! [L, U, P, Q] = lu (s); %! x1 = Q * (U \ (L \ (P * [ones(m,1); zeros(n,1)]))); %! x1 = x1(end - n + 1 : end); %! assert (x1, x0, 1e-6);