which inserted in (10) gives AA' a = b (21) Since the matrix AA' is invertible we have a unique solution a = (AA')-i b (22) which on the basis of (20) gives the solution of our minimum problem and hence the gen- eralized solution of the underdetermined pro- blem defined by equations (10), viz. x0 = A'(AA')-i b (23) The composite matrix on the right of (23) is a generalized inverse of A. Note that since A' is n x m, AA' is m x m and, hence A'(AA')-1 is 11 x m. This operator transforms the m-vector b mto the n-vector x0. The generalized inverse sim- plifies to an ordinary inverse when m = n. To verify that x0 is orthogonal to the null-space N of A, we form the scalar product of x0 with ar>y solution vector s of (13) and apply the bilinear identity (11) s - xo = s • A'(AA')-1 b = As • (AA')-ib = 0 (24) The overdetermined, case When m > n there are too many equations to define a solution of (10). The hyperplanes defined by each of the equations have no com- mon point of intersection. As in the above case °f m = 3^ n = g, we will again define a gener- alized solution on the basis of the vector x0 whose end point S in n-space has the least distance square sum from the m hyperplanes. Since equations (10) have been normalized, x0 ls obtained as the solution of the following niinimum problem M = |Ax — b|2 = min. (25) Using standard techniques again we replace x ln (25) by the varied vector x c gx and form = 2A8X ■ Ax - 2A8x • b = 0 (26) c = 0 which with help of the adjoint A' reduces to (A'Ax - A'b) ■ 8x = 0 (27) Since 8x is an arbitrary vector the solution vector x0 is obtained from A'Ax0 = A'b (28) and hence x0 = (A'A)-1 A'b (29) which is the generalized solution of the over- determined problem. Note that A'A is n x n and (A'A)-1 A' is n x m. Again the operator on the right of (29) transforms the m-vector b into the n-vector x0. It is a generalized inverse of A which simplifies to the ordinary inverse when m = n. It is frequently of interest to introduce a bias into the above procedure. We may want to place unequal weights on the m equations in (10). The numerical bias can be expressed with the help of a diagonal m x m weight matrix W with non-zero diagonal elements and a trace (diagonal sum) equal to unity. Intro- ducing W in equation (25) we now derive the solution of I V W (Ax —b)|2 = ____ (30) | VwAx- Vwbj2 = min. which on the basis of (29) has the solution (31) [(V W A)' Vw A]-1 ( V W A)' V W b Because of the simplicity of the diagonal matrix this expression reduces to x0 = (A'WA)-1 A'Wb (32) Equation (28) indicates that the generalized solution x0 is obtained by operating on both sides of (10) with the adjoint matrix A'. Since the range of A' is orthogonal to the null-space of A, this operation negates all components of b which are in the null-space of A and thereby opens the way for inverting A. It is evident that A' is not the only matrix available for this JÖKULL 23. ÁR 41

Side 1
Side 2
Side 3
Side 4
Side 5
Side 6
Side 7
Side 8
Side 9
Side 10
Side 11
Side 12
Side 13
Side 14
Side 15
Side 16
Side 17
Side 18
Side 19
Side 20
Side 21
Side 22
Side 23
Side 24
Side 25
Side 26
Side 27
Side 28
Side 29
Side 30
Side 31
Side 32
Side 33
Side 34
Side 35
Side 36
Side 37
Side 38
Side 39
Side 40
Side 41
Side 42
Side 43
Side 44
Side 45
Side 46
Side 47
Side 48
Side 49
Side 50
Side 51
Side 52
Side 53
Side 54
Side 55
Side 56
Side 57
Side 58
Side 59
Side 60
Side 61
Side 62
Side 63
Side 64
Side 65
Side 66
Side 67
Side 68
Side 69
Side 70
Side 71
Side 72
Side 73
Side 74
Side 75
Side 76
Side 77
Side 78
Side 79
Side 80
Side 81
Side 82
Side 83
Side 84
Side 85
Side 86
Side 87
Side 88
Side 89
Side 90
Side 91
Side 92
Side 93
Side 94
Side 95
Side 96
Side 97
Side 98
Side 99
Side 100
Side 101
Side 102
Side 103
Side 104
Side 105
Side 106
Side 107
Side 108
Side 109
Side 110
Side 111
Side 112
Side 113
Side 114
Side 115
Side 116
Side 117
Side 118
Side 119
Side 120
Side 121
Side 122
Side 123
Side 124
Side 125
Side 126
Side 127
Side 128
Side 129
Side 130
Side 131
Side 132