- Chapter 1: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.1: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.2: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.3: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.4: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.5: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.6: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 1.7: MATRICES, VECTORS, AND SYSTEMS OF LINEAR EQUATIONS
- Chapter 2: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.1: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.2: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.3: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.4: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.5: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.6: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.7: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 2.8: MATRICES AND LINEAR TRANSFORMATIONS
- Chapter 3: DETERMINANTS
- Chapter 3.1: DETERMINANTS
- Chapter 3.2: DETERMINANTS
- Chapter 4: DETERMINANTS
- Chapter 4.1: SUBSPACES AND THEIR PROPERTIES
- Chapter 4.2: SUBSPACES AND THEIR PROPERTIES
- Chapter 4.3: SUBSPACES AND THEIR PROPERTIES
- Chapter 4.4: DETERMINANTS
- Chapter 4.5: DETERMINANTS
- Chapter 5: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 5.1: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 5.2: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 5.3: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 5.4: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 5.5: EIGENVALUES, EIGENVECTORS, AND DIAGONALIZATION
- Chapter 6.1: ORTHOGONALITY
- Chapter 6.2: ORTHOGONALITY
Elementary Linear Algebra: A Matrix Approach 2nd Edition - Solutions by Chapter
Full solutions for Elementary Linear Algebra: A Matrix Approach | 2nd Edition
ISBN: 9780131871410
Elementary Linear Algebra: A Matrix Approach | 2nd Edition - Solutions by Chapter
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This textbook survival guide was created for the textbook: Elementary Linear Algebra: A Matrix Approach, edition: 2. Elementary Linear Algebra: A Matrix Approach was written by and is associated to the ISBN: 9780131871410. Since problems from 34 chapters in Elementary Linear Algebra: A Matrix Approach have been answered, more than 37611 students have viewed full step-by-step answer. This expansive textbook survival guide covers the following chapters: 34. The full step-by-step solution to problem in Elementary Linear Algebra: A Matrix Approach were answered by , our top Math solution expert on 12/27/17, 07:57PM.
Key Math Terms and definitions covered in this textbook
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Affine transformation
Tv = Av + Vo = linear transformation plus shift.
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Back substitution.
Upper triangular systems are solved in reverse order Xn to Xl.
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Change of basis matrix M.
The old basis vectors v j are combinations L mij Wi of the new basis vectors. The coordinates of CI VI + ... + cnvn = dl wI + ... + dn Wn are related by d = M c. (For n = 2 set VI = mll WI +m21 W2, V2 = m12WI +m22w2.)
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Complete solution x = x p + Xn to Ax = b.
(Particular x p) + (x n in nullspace).
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Determinant IAI = det(A).
Defined by det I = 1, sign reversal for row exchange, and linearity in each row. Then IAI = 0 when A is singular. Also IABI = IAIIBI and
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Echelon matrix U.
The first nonzero entry (the pivot) in each row comes in a later column than the pivot in the previous row. All zero rows come last.
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Fourier matrix F.
Entries Fjk = e21Cijk/n give orthogonal columns FT F = nI. Then y = Fe is the (inverse) Discrete Fourier Transform Y j = L cke21Cijk/n.
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Free columns of A.
Columns without pivots; these are combinations of earlier columns.
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Indefinite matrix.
A symmetric matrix with eigenvalues of both signs (+ and - ).
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Lucas numbers
Ln = 2,J, 3, 4, ... satisfy Ln = L n- l +Ln- 2 = A1 +A~, with AI, A2 = (1 ± -/5)/2 from the Fibonacci matrix U~]' Compare Lo = 2 with Fo = O.
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Nilpotent matrix N.
Some power of N is the zero matrix, N k = o. The only eigenvalue is A = 0 (repeated n times). Examples: triangular matrices with zero diagonal.
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Norm
IIA II. The ".e 2 norm" of A is the maximum ratio II Ax II/l1x II = O"max· Then II Ax II < IIAllllxll and IIABII < IIAIIIIBII and IIA + BII < IIAII + IIBII. Frobenius norm IIAII} = L La~. The.e 1 and.e oo norms are largest column and row sums of laij I.
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Pascal matrix
Ps = pascal(n) = the symmetric matrix with binomial entries (i1~;2). Ps = PL Pu all contain Pascal's triangle with det = 1 (see Pascal in the index).
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Permutation matrix P.
There are n! orders of 1, ... , n. The n! P 's have the rows of I in those orders. P A puts the rows of A in the same order. P is even or odd (det P = 1 or -1) based on the number of row exchanges to reach I.
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Pivot columns of A.
Columns that contain pivots after row reduction. These are not combinations of earlier columns. The pivot columns are a basis for the column space.
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Reduced row echelon form R = rref(A).
Pivots = 1; zeros above and below pivots; the r nonzero rows of R give a basis for the row space of A.
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Solvable system Ax = b.
The right side b is in the column space of A.
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Spectral Theorem A = QAQT.
Real symmetric A has real A'S and orthonormal q's.
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Toeplitz matrix.
Constant down each diagonal = time-invariant (shift-invariant) filter.
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Vector space V.
Set of vectors such that all combinations cv + d w remain within V. Eight required rules are given in Section 3.1 for scalars c, d and vectors v, w.