MathAction SandBoxComplementsdalgebrelineaire

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---
--- linalg.input
--- Francois Maltey - janvier 2008
---
---
--- A  partir de rowEchelon
---
sameSizeVectors? Lb ==
 null Lb => true
 n := #(first Lb)
 every? (t +-> #t=n, rest Lb)

Type: Void

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basis mat ==
 mat2 := rowEchelon mat
 basis := []
 indrow : Integer := 1
 n : Integer := ncols mat
 m : Integer := nrows mat
 for k in 1..n repeat
   if indrow <= m and mat2.(indrow,k) ~= 0
     then
       basis := cons (column (mat, k), basis)
       indrow := indrow + 1
 reverse basis

Type: Void

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basisLV Lv ==
 null Lv => []
 not (sameSizeVectors? Lv) => error "vectors have not the same size"
 basis transpose matrix Lv

Type: Void

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basisMat mat == basis mat

Type: Void

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sumBasisLLV LLv == basisLV concat LLv

Type: Void

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sumBasis2 (Lv1, Lv2) == basisLV concat (Lv1, Lv2)

Type: Void

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kernelMat mat ==
 lv := nullSpace mat
 #lv = 1 and lv.1 = 0*lv.1 => []
 lv

Type: Void

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subVector (v, a, b) == vector (elt (entries v, a..b))

Type: Void

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linearVector (t, Lv) == reduce (+, [t.i*Lv.i for i in 1..#t])

Type: Void

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intBasis2 (Lv1, Lv2) ==
 Lb1 := basisLV Lv1
 Lb2 := basisLV Lv2
 null Lb1 => []
 null Lb2 => []
 #(first Lb1) ~= #(first Lb2) => error "vectors have not the same size"
 lkv := kernelMat transpose matrix concat (Lb2, Lb1)
 d1 := #Lb1
 d2 := #Lb2
 LcoeffV1 := [subVector (kv, d2+1, d1+d2) for kv in lkv]
 [linearVector (cc, Lb1) for cc in LcoeffV1]

Type: Void

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intBasisLLV LLv ==
 #LLv = 0 => error "no space to intersect"
 #LLv = 1 => LLv.1
--reduce (intBasis2, LLv)
 intBasis2 (LLv.1, intBasisLLV rest LLv)

Type: Void

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---
--- inversegeneralisee.input
--- Francois Maltey - janvier 2008
---
--- inverse generalisee
---
--- a partir du livre Algebre lineaire par Joseph Grifone p.375
--- applique pas à pas la méthode du livre à l'exemple

A := matrix [[2,1,-1,1],[1,1,0,1],[3,2,-1,2]]

$\label{eq1}\left[ \begin{array}{cccc} 2 & 1 & - 1 & 1 \ 1 & 1 & 0 & 1 \ 3 & 2 & - 1 & 2$

(1)

Type: Matrix(Integer)

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--- kerA est une base de ker f ou f est definie par la matrice A

KerA  := kernelMat A

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Compiling function kernelMat with type Matrix(Integer) -> List(
      Vector(Integer))

$\label{eq2}\left[{\left[ 1, \: - 1, \: 1, \: 0 \right]}, \:{\left[ 0, \: - 1, \: 0, \: 1 \right]}\right]$

(2)

Type: List(Vector(Integer))

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--- Le noyau de la matrice dont les lignes sont des vecteurs generateurs
--- d'un sev est le sev orthogonal. C'est un sous-espace supplementaire.
--- baseF est une base d'un sous-espace supplémentaire de ker f

baseF := kernelMat matrix KerA

$\label{eq3}\left[{\left[ - 1, \: 0, \: 1, \: 0 \right]}, \:{\left[ 1, \: 1, \: 0, \: 1 \right]}\right]$

(3)

Type: List(Vector(Integer))

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--- les vecteurs colonnes de A engendre l'image Im f.
--- baseImA est une base de l'image de f calculee a partir de la matrice A

baseImA := basis A

   Function definition for basis is being overwritten.
   The type of the local variable basis has changed in the computation.
   We will attempt to interpret the code.
   Compiled code for basis has been cleared.

$\label{eq4}\left[{\left[ 2, \: 1, \: 3 \right]}, \:{\left[ 1, \: 1, \: 2 \right]}\right]$

(4)

Type: List(Vector(Integer))

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--- baseG et baseG2 sont deux bases d'un sous-espace supplementaire de Im f
--- l'une calculee a partir de la matrice A, l'autre d'une base de Im f.

baseG := kernelMat transpose A

$\label{eq5}\left[{\left[ - 1, \: - 1, \: 1 \right]}\right]$

(5)

Type: List(Vector(Integer))

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baseG2:= kernelMat matrix baseImA

$\label{eq6}\left[{\left[ - 1, \: - 1, \: 1 \right]}\right]$

(6)

Type: List(Vector(Integer))

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--- La restriction g de f est un isomorphisme du supplementaire F de ker f
--- dans Im f. La matrice de g dans les bases de F et de Im f est obtenue
--- en decomposant dans Im f les images des vecteurs de la base de F.
--- La commande particularSolution effectue cette decomposition.

MP := transpose matrix baseImA

$\label{eq7}\left[ \begin{array}{cc} 2 & 1 \ 1 & 1 \ 3 & 2$

(7)

Type: Matrix(Integer)

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map (X +-> A*X, baseF)

$\label{eq8}\left[{\left[ - 3, \: - 1, \: - 4 \right]}, \:{\left[ 4, \: 3, \: 7 \right]}\right]$

(8)

Type: List(Vector(Integer))

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map (X +-> particularSolution (MP, A*X), baseF)

$\label{eq9}\left[{\left[ - 2, \: 1 \right]}, \:{\left[ 1, \: 2 \right]}\right]$

(9)

Type: List(Union(Vector(Fraction(Integer)),"failed"))

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B := transpose matrix map (X +-> particularSolution (MP, A*X), baseF)

$\label{eq10}\left[ \begin{array}{cc} - 2 & 1 \ 1 & 2$

(10)

Type: Matrix(Fraction(Integer))

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--- La matrice C est celle de l'isomorphisme reciproque dans ces bases.

C := B^-1

$\label{eq11}\left[ \begin{array}{cc} -{2 \over 5}&{1 \over 5} \ {1 \over 5}&{2 \over 5}$

(11)

Type: Matrix(Fraction(Integer))

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--- la projection orthogonale de E' sur Im f peut être obtenue
--- à partir d'une base orthonormee de Im f.
--- baseImA est une base de Im f, la fonction gramschmidt construit
--- la bon associee.

GS := gramschmidt (baseImA::List Vector Expression Integer)

$\label{eq12}\begin{array}{@{}l} \displaystyle \left[{\left[ \begin{array}{c} -{{2 \ {\sqrt{14}}}\over{7 \ {\sqrt{3}}}} \ {{5 \ {\sqrt{14}}}\over{{14}\ {\sqrt{3}}}} \ {{\sqrt{14}}\over{{14}\ {\sqrt{3}}}}$

(12)

Type: List(Matrix(Expression(Integer)))

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bonImA := map (M +-> column (M, 1), GS)

$\label{eq13}\left[{\left[ -{{2 \ {\sqrt{14}}}\over{7 \ {\sqrt{3}}}}, \:{{5 \ {\sqrt{14}}}\over{{14}\ {\sqrt{3}}}}, \:{{\sqrt{14}}\over{{1 4}\ {\sqrt{3}}}}\right]}, \:{\left[{2 \over{\sqrt{14}}}, \:{1 \over{\sqrt{14}}}, \:{3 \over{\sqrt{14}}}\right]}\right]$

(13)

Type: List(Vector(Expression(Integer)))

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projortho X ==
 reduce (+, map (V +-> dot (V, X::Vector Expression Integer) * V, bonImA))

Type: Void

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--- exemple de projection orthogonale sur Im f.

projortho vector [1,2,4]

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Compiling function projortho with type Vector(PositiveInteger) -> 
      Vector(Expression(Integer))

$\label{eq14}\left[{4 \over 3}, \:{7 \over 3}, \:{{11}\over 3}\right]$

(14)

Type: Vector(Expression(Integer))

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--- construction de la composition g^-1 o p de E' dans E
--- en calculant les images des vecteurs de la base canonique de E'
--- puis passage des coordonnees de g^-1 o p de la base de F
--- à la base canonique de E.

Id3 := diagonalMatrix [1 for i in 1..3]

$\label{eq15}\left[ \begin{array}{ccc} 1 & 0 & 0 \ 0 & 1 & 0 \ 0 & 0 & 1$

(15)

Type: Matrix(Integer)

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RES1 := [projortho column (Id3, i) for i in 1..3]

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Compiling function projortho with type Vector(Integer) -> Vector(
      Expression(Integer))

$\label{eq16}\left[{\left[{2 \over 3}, \: -{1 \over 3}, \:{1 \over 3}\right]}, \:{\left[ -{1 \over 3}, \:{2 \over 3}, \:{1 \over 3}\right]}, \:{\left[{1 \over 3}, \:{1 \over 3}, \:{2 \over 3}\right]}\right]$

(16)

Type: List(Vector(Expression(Integer)))

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RES2 := [X::Vector Fraction Integer for X in RES1]

$\label{eq17}\left[{\left[{2 \over 3}, \: -{1 \over 3}, \:{1 \over 3}\right]}, \:{\left[ -{1 \over 3}, \:{2 \over 3}, \:{1 \over 3}\right]}, \:{\left[{1 \over 3}, \:{1 \over 3}, \:{2 \over 3}\right]}\right]$

(17)

Type: List(Vector(Fraction(Integer)))

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RES3 := [particularSolution (MP, X) for X in RES2]

$\label{eq18}\left[{\left[ 1, \: -{4 \over 3}\right]}, \:{\left[ - 1, \:{5 \over 3}\right]}, \:{\left[ 0, \:{1 \over 3}\right]}\right]$

(18)

Type: List(Union(Vector(Fraction(Integer)),"failed"))

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RES := [C * X for X in RES3::List Vector Fraction Integer]

$\label{eq19}\left[{\left[ -{2 \over 3}, \: -{1 \over 3}\right]}, \:{\left[{{1 1}\over{15}}, \:{7 \over{15}}\right]}, \:{\left[{1 \over{15}}, \:{2 \over{15}}\right]}\right]$

(19)

Type: List(Vector(Fraction(Integer)))

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AA := transpose matrix baseF * transpose matrix RES

$\label{eq20}\left[ \begin{array}{ccc} {1 \over 3}& -{4 \over{15}}&{1 \over{15}} \ -{1 \over 3}&{7 \over{15}}&{2 \over{15}} \ -{2 \over 3}&{{11}\over{15}}&{1 \over{15}} \ -{1 \over 3}&{7 \over{15}}&{2 \over{15}}$

(20)

Type: Matrix(Fraction(Integer))

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--- vérifications de quelques propriétés : A AA A = A et AA A AA = AA
--- transpose (A AA) = A AA : car les sev choisis sont des orthogonaux

AA * A * AA - AA

$\label{eq21}\left[ \begin{array}{ccc} 0 & 0 & 0 \ 0 & 0 & 0 \ 0 & 0 & 0 \ 0 & 0 & 0$

(21)

Type: Matrix(Fraction(Integer))

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A * AA * A - A

$\label{eq22}\left[ \begin{array}{cccc} 0 & 0 & 0 & 0 \ 0 & 0 & 0 & 0 \ 0 & 0 & 0 & 0$

(22)

Type: Matrix(Fraction(Integer))

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transpose (AA * A) - AA * A

$\label{eq23}\left[ \begin{array}{cccc} 0 & 0 & 0 & 0 \ 0 & 0 & 0 & 0 \ 0 & 0 & 0 & 0 \ 0 & 0 & 0 & 0$

(23)

Type: Matrix(Fraction(Integer))

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transpose (A * AA) - A * AA

$\label{eq24}\left[ \begin{array}{ccc} 0 & 0 & 0 \ 0 & 0 & 0 \ 0 & 0 & 0$

(24)

Type: Matrix(Fraction(Integer))

Subject: Be Bold !!

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