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Chapter 5 Chapter Content 1. Real Vector Spaces 2. Subspaces 3. Linear Independence 4. Basis and Dimension 5. Row Space, Column Space, and Nullspace 6.

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Presentation on theme: "Chapter 5 Chapter Content 1. Real Vector Spaces 2. Subspaces 3. Linear Independence 4. Basis and Dimension 5. Row Space, Column Space, and Nullspace 6."— Presentation transcript:

1 Chapter 5 Chapter Content 1. Real Vector Spaces 2. Subspaces 3. Linear Independence 4. Basis and Dimension 5. Row Space, Column Space, and Nullspace 6. Rank and Nullity

2 Definition (Vector Space) Let V be an arbitrary nonempty set of objects on which two operations are defined: addition, and multiplication by scalars. If the following axioms are satisfied by all objects u, v, w in V and all scalars k and m, then we call V a vector space and we call the objects in V vectors 1.If u and v are objects in V, then u + v is in V. 2. u + v = v + u 3. u + (v + w) = (u + v) + w 4. There is an object 0 in V, called a zero vector for V, such that 0 + u= u + 0 = u for all u in V. 5. For each u in V, there is an object -u in V, called a negative of u, such that u + (-u) = (-u) + u = 0. 6. If k is any scalar and u is any object in V, then ku is in V. 7. k (u + v) = ku + kv 8. (k + m) u = ku + mu 9. k (mu) = (km) (u) 10. 1u = u

3 Remarks Depending on the application, scalars may be real numbers or complex numbers. Vector spaces in which the scalars are complex numbers are called complex vector spaces, and those in which the scalars must be real are called real vector spaces. The definition of a vector space specifies neither the nature of the vectors nor the operations. Any kind of object can be a vector, and the operations of addition and scalar multiplication may not have any relationship or similarity to the standard vector operations on. The only requirement is that the ten vector space axioms be satisfied.

4 Example ( Is a Vector Space) The set V = with the standard operations of addition and scalar multiplication is a vector space. (Axioms 1 and 6 follow from the definitions of the standard operations on ; the remaining axioms follow from Theorem 4.1.1.) The three most important special cases of are R (the real numbers), (the vectors in the plane), and (the vectors in 3-space).

5 Example (2×2 Matrices) Show that the set V of all 2×2 matrices with real entries is a vector space if vector addition is defined to be matrix addition and vector scalar multiplication is defined to be matrix scalar multiplication. Solution: Let and (1)we must show that u + v is a 2×2 matrix. (2)Want to show that u + v = v + u (3)Similarly we can show that u + ( v + w ) = ( u + v )+ w. (4)Define 0 to be such that

6 (5) Define the negative of u to be such that (6) If k is any scalar and u is a 2X2 matrix, then is 2X2 matrix. (7)-(9) will be obtained by similar approach. (10) Thus, the set V of all 2×2 matrices with real entries is a vector space.

7 Solution: We must check all ten properties: (1)If (x, y, z) and (x’, y’, z’) are triples of real numbers, so is (x, y, z) + (x’, y’, z’) = (x + x’, y +y’, z + z’). (2) (x, y, z) + (x’, y’, z’) = (x + x’, y + y’, z + z’)= (x’, y’, z’) + (x, y, z). (3) (x, y, z) + [(x’, y’, z’) + (x’’, y’’, z’’)] = (x, y, z) + [(x’, y’, z’) + (x’’, y’’, z’’)]. (4) There is an object 0, (0, 0, 0), such that (0, 0, 0) + (x, y, z) = (x, y, z) + (0, 0, 0)= (x, y, z). (5) For each positive real x, (-x, -y, -z) acts as the negative: (x, y, z) + (-x, -y, -z) = (-x, -y, -z) + (x, y, z) =(x, y, z) Example: Given the set of all triples of real numbers ( x, y, z ) with the operations Show that it’s a vector space under the given operation.

8 (6) If k is a real and (x, y, z) is a triple of real numbers, then k (x, y, z) = (kx, y, z) is again a triple of real numbers. (7) k[(x, y, z) + (x’, y’, z’)] = (k(x+x’), y+y’, z+z’) = k(x, y, z) + k(x’, y’, z’) (8) (k + m) (x, y, z) = ((k + m)x, y, z) = k (x, y, z) + m(x, y, z) (9) k(m(x, y, z)) = (kmx, y, z) = (km)(x, y, z) (10) 1 (x, y, z) = (x, y, z) Thus, the set of all triples of real numbers ( x, y, z ) with the operations is a vector space under the given operation.

9 Example (Not a Vector Space) Let V = R2 and define addition and scalar multiplication operations as follows: If u = (u 1, u 2 ) and v = (v 1, v 2 ), then define u + v = (u 1 + v 1, u 2 + v 2 ) and if k is any real number, then define k u = (k u 1, 0) There are values of u for which Axiom 10 fails to hold. For example, if u = (u 1, u 2 ) is such that u 2 ≠ 0,then 1u = 1 (u 1, u 2 ) = (1 u 1, 0) = (u 1, 0) ≠ u Thus, V is not a vector space with the stated operations

10 The Zero Vector Space Let V consist of a single object, which we denote by 0, and define 0 + 0 = 0 and k 0 = 0 for all scalars k. It’s easy to check that all the vector space axioms are satisfied. We called this the zero vector space.

11 Theorem 5.1.1 Let V be a vector space, u be a vector in V, and k a scalar; then: (a) 0 u = 0 (b) k 0 = 0 (c) (-1) u = -u (d) If k u = 0, then k = 0 or u = 0.

12 5.2 Subspaces Definition A subset W of a vector space V is called a subspace of V if W is itself a vector space under the addition and scalar multiplication defined on V. Theorem 5.2.1 If W is a set of one or more vectors from a vector space V, then W is a subspace of V if and only if the following conditions hold: a) If u and v are vectors in W, then u + v is in W. b) If k is any scalar and u is any vector in W, then ku is in W. Remark Theorem 5.2.1 states that W is a subspace of V if and only if W is a closed under addition (condition (a)) and closed under scalar multiplication (condition (b)).

13 Example All vectors of the form (a, 0, 0) is a subspace of R3. The set is closed under vector addition because (a, 0, 0) + (b, 0, 0) = (a + b, 0, 0) It is closed under scalar multiplication because k(a, 0, 0) = (ka, 0, 0) Therefore it is a subspace of R3.

14 Example (Not a Subspace) Let W be the set of all points (x, y) in R2 such that x ≥ 0 and y ≥ 0. These are the points in the first quadrant. The set W is not a subspace of R2 since it is not closed under scalar multiplication. For example, v = (1, 1) lines in W, but its negative (-1)v = -v = (-1, -1) does not.

15 Subspaces of M nn The set of n×n diagonal matrices forms subspaces of M nn, since each of these sets is closed under addition and scalar multiplication. This set is closed under vector addition since the sum of two integers is again an integer. However, it is not closed under scalar multiplication since the product ku where k is real and a is an integer need not be an integer. Thus, the set is not a subspace. The set of n×n matrices with integer entries is NOT a subspace of the vector space M nn of n×n matrices.

16 Solution Space Solution Space of Homogeneous Systems If Ax = b is a system of the linear equations, then each vector x that satisfies this equation is called a solution vector of the system. Theorem 5.2.2 If Ax = 0 is a homogeneous linear system of m equations in n unknowns, then the set of solution vectors is a subspace of Rn. Remark: Theorem 5.2.2 shows that the solution vectors of a homogeneous linear system form a vector space, which we shall call the solution space of the system.

17 Linear Combination Definition A vector w is a linear combination of the vectors v 1, v 2,…, v r if it can be expressed in the form w = k 1 v 1 + k 2 v 2 + · · · + k r v r where k 1, k 2, …, k r are scalars. Example:Vectors in R3 are linear combinations of i, j, and k Every vector v = (a, b, c) in R3 is expressible as a linear combination of the standard basis vectors i = (1, 0, 0), j = (0, 1, 0), k = (0, 0, 1) Since v= a(1, 0, 0) + b(0, 1, 0) + c(0, 0, 1) = a i + b j + c k

18 Example Consider the vectors u = (1, 2, -1) and v = (6, 4, 2) in R3. Show that w = (9, 2, 7) is a linear combination of u and v and that w′ = (4, -1, 8) is not a linear combination of u and v. Solution. In order for w to be a linear combination of u and v, there must be scalars k 1 and k 2 such that w = k 1 u + k 2 v; (9, 2, 7) = (k 1 + 6k 2, 2k 1 + 4k 2, -k 1 + 2k 2 ) Equating corresponding components gives k 1 + 6k 2 = 9 2k 1 + 4k 2 = 2 -k 1 + 2k 2 = 7 Solving this system yields k 1 = -3, k 2 = 2, so w = -3u + 2v

19 Similarly, for w‘ to be a linear combination of u and v, there must be scalars k 1 and k 2 such that w'= k 1 u + k 2 v; (4, -1, 8) = k 1 (1, 2, -1) + k 2 (6, 4, 2) or (4, -1, 8) = (k 1 + 6k 2, 2k 1 + 4k 2, -k 1 + 2k 2 ) Equating corresponding components gives k 1 + 6k 2 = 4 2 k 1 + 4k 2 = -1 - k 1 + 2k 2 = 8 This system of equation is inconsistent, so no such scalars k 1 and k 2 exist. Consequently, w' is not a linear combination of u and v.

20 Linear Combination and Spanning Theorem 5.2.3 If v 1, v 2, …, v r are vectors in a vector space V, then: (a)The set W of all linear combinations of v 1, v 2, …, v r is a subspace of V. (b) W is the smallest subspace of V that contain v 1, v 2, …, v r in the sense that every other subspace of V that contain v 1, v 2, …, v r must contain W. Definition If S = {v 1, v 2, …, v r } is a set of vectors in a vector space V, then the subspace W of V containing of all linear combination of these vectors in S is called the space spanned by v 1, v 2, …, v r, and we say that the vectors v 1, v 2, …, v r span W. To indicate that W is the space spanned by the vectors in the set S = {v 1, v 2, …, v r }, we write W = span (S) or W = span{v 1, v 2, …, v r }.

21 Example If v 1 and v 2 are non-collinear vectors in R3 with their initial points at the origin, then span{v 1, v 2 }, which consists of all linear combinations k 1 v 1 + k 2 v 2 is the plane determined by v 1 and v 2. Similarly, if v is a nonzero vector in R2 and R3, then span {v}, which is the set of all scalar multiples kv, is the line determined by v.

22 Example Determine whether v 1 = (1, 1, 2), v 2 = (1, 0, 1), and v 3 = (2, 1, 3) span the vector space R3. Solution Is it possible that an arbitrary vector b = (b 1, b 2, b 3 ) in R3 can be expressed as a linear combination b = k 1 v 1 + k 2 v 2 + k 3 v 3 ? b = (b 1, b 2, b 3 ) = k 1 (1, 1, 3) + k 2 (1, 0, 1) + k 3 (2, 1, 3) = (k 1 +k 2 +2k 3, k 1 +k 3, 2k 1 +k 2 +3k 3 ) Or k 1 + k 2 + 2k 3 = b 1 k 1 + k 3 = b 2 2k 1 + k 2 + 3 k 3 = b 3 This system is consistent for all values of b 1, b 2, and b 3 if and only if the coefficient matrix has a nonzero determinant. However, det(A) = 0, so that v 1, v 2, and v 3, do not span R3.

23 Theorem 5.2.4 If S = {v 1, v 2, …, v r } and S′ = {w 1, w 2, …, w r } are two sets of vector in a vector space V, then span{v 1, v 2, …, v r } = span{w 1, w 2, …, w r } if and only if each vector in S is a linear combination of these in S′ and each vector in S′ is a linear combination of these in S.

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