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source: trunk/sources/ALGLIB/inverseupdate.cs @ 2567

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Last change on this file since 2567 was 2563, checked in by gkronber, 15 years ago
Updated ALGLIB to latest version. #751 (Plugin for for data-modeling with ANN (integrated into CEDMA))
File size: 15.9 KB

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[2563]	1	/*************************************************************************
	2	Copyright (c) 2005-2007, Sergey Bochkanov (ALGLIB project).
	3
	4	>>> SOURCE LICENSE >>>
	5	This program is free software; you can redistribute it and/or modify
	6	it under the terms of the GNU General Public License as published by
	7	the Free Software Foundation (www.fsf.org); either version 2 of the
	8	License, or (at your option) any later version.
	9
	10	This program is distributed in the hope that it will be useful,
	11	but WITHOUT ANY WARRANTY; without even the implied warranty of
	12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	13	GNU General Public License for more details.
	14
	15	A copy of the GNU General Public License is available at
	16	http://www.fsf.org/licensing/licenses
	17
	18	>>> END OF LICENSE >>>
	19	*************************************************************************/
	20
	21	using System;
	22
	23	namespace alglib
	24	{
	25	public class inverseupdate
	26	{
	27	/*************************************************************************
	28	Inverse matrix update by the Sherman-Morrison formula
	29
	30	The algorithm updates matrix A^-1 when adding a number to an element
	31	of matrix A.
	32
	33	Input parameters:
	34	InvA - inverse of matrix A.
	35	Array whose indexes range within [0..N-1, 0..N-1].
	36	N - size of matrix A.
	37	UpdRow - row where the element to be updated is stored.
	38	UpdColumn - column where the element to be updated is stored.
	39	UpdVal - a number to be added to the element.
	40
	41
	42	Output parameters:
	43	InvA - inverse of modified matrix A.
	44
	45	-- ALGLIB --
	46	Copyright 2005 by Bochkanov Sergey
	47	*************************************************************************/
	48	public static void rmatrixinvupdatesimple(ref double[,] inva,
	49	int n,
	50	int updrow,
	51	int updcolumn,
	52	double updval)
	53	{
	54	double[] t1 = new double[0];
	55	double[] t2 = new double[0];
	56	int i = 0;
	57	int j = 0;
	58	double lambda = 0;
	59	double vt = 0;
	60	int i_ = 0;
	61
	62	System.Diagnostics.Debug.Assert(updrow>=0 & updrow<n, "RMatrixInvUpdateSimple: incorrect UpdRow!");
	63	System.Diagnostics.Debug.Assert(updcolumn>=0 & updcolumn<n, "RMatrixInvUpdateSimple: incorrect UpdColumn!");
	64	t1 = new double[n-1+1];
	65	t2 = new double[n-1+1];
	66
	67	//
	68	// T1 = InvA * U
	69	//
	70	for(i_=0; i_<=n-1;i_++)
	71	{
	72	t1[i_] = inva[i_,updrow];
	73	}
	74
	75	//
	76	// T2 = v*InvA
	77	//
	78	for(i_=0; i_<=n-1;i_++)
	79	{
	80	t2[i_] = inva[updcolumn,i_];
	81	}
	82
	83	//
	84	// Lambda = v * InvA * U
	85	//
	86	lambda = updval*inva[updcolumn,updrow];
	87
	88	//
	89	// InvA = InvA - correction
	90	//
	91	for(i=0; i<=n-1; i++)
	92	{
	93	vt = updval*t1[i];
	94	vt = vt/(1+lambda);
	95	for(i_=0; i_<=n-1;i_++)
	96	{
	97	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	98	}
	99	}
	100	}
	101
	102
	103	/*************************************************************************
	104	Inverse matrix update by the Sherman-Morrison formula
	105
	106	The algorithm updates matrix A^-1 when adding a vector to a row
	107	of matrix A.
	108
	109	Input parameters:
	110	InvA - inverse of matrix A.
	111	Array whose indexes range within [0..N-1, 0..N-1].
	112	N - size of matrix A.
	113	UpdRow - the row of A whose vector V was added.
	114	0 <= Row <= N-1
	115	V - the vector to be added to a row.
	116	Array whose index ranges within [0..N-1].
	117
	118	Output parameters:
	119	InvA - inverse of modified matrix A.
	120
	121	-- ALGLIB --
	122	Copyright 2005 by Bochkanov Sergey
	123	*************************************************************************/
	124	public static void rmatrixinvupdaterow(ref double[,] inva,
	125	int n,
	126	int updrow,
	127	ref double[] v)
	128	{
	129	double[] t1 = new double[0];
	130	double[] t2 = new double[0];
	131	int i = 0;
	132	int j = 0;
	133	double lambda = 0;
	134	double vt = 0;
	135	int i_ = 0;
	136
	137	t1 = new double[n-1+1];
	138	t2 = new double[n-1+1];
	139
	140	//
	141	// T1 = InvA * U
	142	//
	143	for(i_=0; i_<=n-1;i_++)
	144	{
	145	t1[i_] = inva[i_,updrow];
	146	}
	147
	148	//
	149	// T2 = v*InvA
	150	// Lambda = v * InvA * U
	151	//
	152	for(j=0; j<=n-1; j++)
	153	{
	154	vt = 0.0;
	155	for(i_=0; i_<=n-1;i_++)
	156	{
	157	vt += v[i_]*inva[i_,j];
	158	}
	159	t2[j] = vt;
	160	}
	161	lambda = t2[updrow];
	162
	163	//
	164	// InvA = InvA - correction
	165	//
	166	for(i=0; i<=n-1; i++)
	167	{
	168	vt = t1[i]/(1+lambda);
	169	for(i_=0; i_<=n-1;i_++)
	170	{
	171	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	172	}
	173	}
	174	}
	175
	176
	177	/*************************************************************************
	178	Inverse matrix update by the Sherman-Morrison formula
	179
	180	The algorithm updates matrix A^-1 when adding a vector to a column
	181	of matrix A.
	182
	183	Input parameters:
	184	InvA - inverse of matrix A.
	185	Array whose indexes range within [0..N-1, 0..N-1].
	186	N - size of matrix A.
	187	UpdColumn - the column of A whose vector U was added.
	188	0 <= UpdColumn <= N-1
	189	U - the vector to be added to a column.
	190	Array whose index ranges within [0..N-1].
	191
	192	Output parameters:
	193	InvA - inverse of modified matrix A.
	194
	195	-- ALGLIB --
	196	Copyright 2005 by Bochkanov Sergey
	197	*************************************************************************/
	198	public static void rmatrixinvupdatecolumn(ref double[,] inva,
	199	int n,
	200	int updcolumn,
	201	ref double[] u)
	202	{
	203	double[] t1 = new double[0];
	204	double[] t2 = new double[0];
	205	int i = 0;
	206	int j = 0;
	207	double lambda = 0;
	208	double vt = 0;
	209	int i_ = 0;
	210
	211	t1 = new double[n-1+1];
	212	t2 = new double[n-1+1];
	213
	214	//
	215	// T1 = InvA * U
	216	// Lambda = v * InvA * U
	217	//
	218	for(i=0; i<=n-1; i++)
	219	{
	220	vt = 0.0;
	221	for(i_=0; i_<=n-1;i_++)
	222	{
	223	vt += inva[i,i_]*u[i_];
	224	}
	225	t1[i] = vt;
	226	}
	227	lambda = t1[updcolumn];
	228
	229	//
	230	// T2 = v*InvA
	231	//
	232	for(i_=0; i_<=n-1;i_++)
	233	{
	234	t2[i_] = inva[updcolumn,i_];
	235	}
	236
	237	//
	238	// InvA = InvA - correction
	239	//
	240	for(i=0; i<=n-1; i++)
	241	{
	242	vt = t1[i]/(1+lambda);
	243	for(i_=0; i_<=n-1;i_++)
	244	{
	245	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	246	}
	247	}
	248	}
	249
	250
	251	/*************************************************************************
	252	Inverse matrix update by the Sherman-Morrison formula
	253
	254	The algorithm computes the inverse of matrix A+u*v by using the given matrix
	255	A^-1 and the vectors u and v.
	256
	257	Input parameters:
	258	InvA - inverse of matrix A.
	259	Array whose indexes range within [0..N-1, 0..N-1].
	260	N - size of matrix A.
	261	U - the vector modifying the matrix.
	262	Array whose index ranges within [0..N-1].
	263	V - the vector modifying the matrix.
	264	Array whose index ranges within [0..N-1].
	265
	266	Output parameters:
	267	InvA - inverse of matrix A + u*v'.
	268
	269	-- ALGLIB --
	270	Copyright 2005 by Bochkanov Sergey
	271	*************************************************************************/
	272	public static void rmatrixinvupdateuv(ref double[,] inva,
	273	int n,
	274	ref double[] u,
	275	ref double[] v)
	276	{
	277	double[] t1 = new double[0];
	278	double[] t2 = new double[0];
	279	int i = 0;
	280	int j = 0;
	281	double lambda = 0;
	282	double vt = 0;
	283	int i_ = 0;
	284
	285	t1 = new double[n-1+1];
	286	t2 = new double[n-1+1];
	287
	288	//
	289	// T1 = InvA * U
	290	// Lambda = v * T1
	291	//
	292	for(i=0; i<=n-1; i++)
	293	{
	294	vt = 0.0;
	295	for(i_=0; i_<=n-1;i_++)
	296	{
	297	vt += inva[i,i_]*u[i_];
	298	}
	299	t1[i] = vt;
	300	}
	301	lambda = 0.0;
	302	for(i_=0; i_<=n-1;i_++)
	303	{
	304	lambda += v[i_]*t1[i_];
	305	}
	306
	307	//
	308	// T2 = v*InvA
	309	//
	310	for(j=0; j<=n-1; j++)
	311	{
	312	vt = 0.0;
	313	for(i_=0; i_<=n-1;i_++)
	314	{
	315	vt += v[i_]*inva[i_,j];
	316	}
	317	t2[j] = vt;
	318	}
	319
	320	//
	321	// InvA = InvA - correction
	322	//
	323	for(i=0; i<=n-1; i++)
	324	{
	325	vt = t1[i]/(1+lambda);
	326	for(i_=0; i_<=n-1;i_++)
	327	{
	328	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	329	}
	330	}
	331	}
	332
	333
	334	public static void shermanmorrisonsimpleupdate(ref double[,] inva,
	335	int n,
	336	int updrow,
	337	int updcolumn,
	338	double updval)
	339	{
	340	double[] t1 = new double[0];
	341	double[] t2 = new double[0];
	342	int i = 0;
	343	int j = 0;
	344	double lambda = 0;
	345	double vt = 0;
	346	int i_ = 0;
	347
	348	t1 = new double[n+1];
	349	t2 = new double[n+1];
	350
	351	//
	352	// T1 = InvA * U
	353	//
	354	for(i_=1; i_<=n;i_++)
	355	{
	356	t1[i_] = inva[i_,updrow];
	357	}
	358
	359	//
	360	// T2 = v*InvA
	361	//
	362	for(i_=1; i_<=n;i_++)
	363	{
	364	t2[i_] = inva[updcolumn,i_];
	365	}
	366
	367	//
	368	// Lambda = v * InvA * U
	369	//
	370	lambda = updval*inva[updcolumn,updrow];
	371
	372	//
	373	// InvA = InvA - correction
	374	//
	375	for(i=1; i<=n; i++)
	376	{
	377	vt = updval*t1[i];
	378	vt = vt/(1+lambda);
	379	for(i_=1; i_<=n;i_++)
	380	{
	381	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	382	}
	383	}
	384	}
	385
	386
	387	public static void shermanmorrisonupdaterow(ref double[,] inva,
	388	int n,
	389	int updrow,
	390	ref double[] v)
	391	{
	392	double[] t1 = new double[0];
	393	double[] t2 = new double[0];
	394	int i = 0;
	395	int j = 0;
	396	double lambda = 0;
	397	double vt = 0;
	398	int i_ = 0;
	399
	400	t1 = new double[n+1];
	401	t2 = new double[n+1];
	402
	403	//
	404	// T1 = InvA * U
	405	//
	406	for(i_=1; i_<=n;i_++)
	407	{
	408	t1[i_] = inva[i_,updrow];
	409	}
	410
	411	//
	412	// T2 = v*InvA
	413	// Lambda = v * InvA * U
	414	//
	415	for(j=1; j<=n; j++)
	416	{
	417	vt = 0.0;
	418	for(i_=1; i_<=n;i_++)
	419	{
	420	vt += v[i_]*inva[i_,j];
	421	}
	422	t2[j] = vt;
	423	}
	424	lambda = t2[updrow];
	425
	426	//
	427	// InvA = InvA - correction
	428	//
	429	for(i=1; i<=n; i++)
	430	{
	431	vt = t1[i]/(1+lambda);
	432	for(i_=1; i_<=n;i_++)
	433	{
	434	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	435	}
	436	}
	437	}
	438
	439
	440	public static void shermanmorrisonupdatecolumn(ref double[,] inva,
	441	int n,
	442	int updcolumn,
	443	ref double[] u)
	444	{
	445	double[] t1 = new double[0];
	446	double[] t2 = new double[0];
	447	int i = 0;
	448	int j = 0;
	449	double lambda = 0;
	450	double vt = 0;
	451	int i_ = 0;
	452
	453	t1 = new double[n+1];
	454	t2 = new double[n+1];
	455
	456	//
	457	// T1 = InvA * U
	458	// Lambda = v * InvA * U
	459	//
	460	for(i=1; i<=n; i++)
	461	{
	462	vt = 0.0;
	463	for(i_=1; i_<=n;i_++)
	464	{
	465	vt += inva[i,i_]*u[i_];
	466	}
	467	t1[i] = vt;
	468	}
	469	lambda = t1[updcolumn];
	470
	471	//
	472	// T2 = v*InvA
	473	//
	474	for(i_=1; i_<=n;i_++)
	475	{
	476	t2[i_] = inva[updcolumn,i_];
	477	}
	478
	479	//
	480	// InvA = InvA - correction
	481	//
	482	for(i=1; i<=n; i++)
	483	{
	484	vt = t1[i]/(1+lambda);
	485	for(i_=1; i_<=n;i_++)
	486	{
	487	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	488	}
	489	}
	490	}
	491
	492
	493	public static void shermanmorrisonupdateuv(ref double[,] inva,
	494	int n,
	495	ref double[] u,
	496	ref double[] v)
	497	{
	498	double[] t1 = new double[0];
	499	double[] t2 = new double[0];
	500	int i = 0;
	501	int j = 0;
	502	double lambda = 0;
	503	double vt = 0;
	504	int i_ = 0;
	505
	506	t1 = new double[n+1];
	507	t2 = new double[n+1];
	508
	509	//
	510	// T1 = InvA * U
	511	// Lambda = v * T1
	512	//
	513	for(i=1; i<=n; i++)
	514	{
	515	vt = 0.0;
	516	for(i_=1; i_<=n;i_++)
	517	{
	518	vt += inva[i,i_]*u[i_];
	519	}
	520	t1[i] = vt;
	521	}
	522	lambda = 0.0;
	523	for(i_=1; i_<=n;i_++)
	524	{
	525	lambda += v[i_]*t1[i_];
	526	}
	527
	528	//
	529	// T2 = v*InvA
	530	//
	531	for(j=1; j<=n; j++)
	532	{
	533	vt = 0.0;
	534	for(i_=1; i_<=n;i_++)
	535	{
	536	vt += v[i_]*inva[i_,j];
	537	}
	538	t2[j] = vt;
	539	}
	540
	541	//
	542	// InvA = InvA - correction
	543	//
	544	for(i=1; i<=n; i++)
	545	{
	546	vt = t1[i]/(1+lambda);
	547	for(i_=1; i_<=n;i_++)
	548	{
	549	inva[i,i_] = inva[i,i_] - vt*t2[i_];
	550	}
	551	}
	552	}
	553	}
	554	}

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