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Chapter 6- LINEAR MAPPINGS LECTURE 8

Chapter 6- LINEAR MAPPINGS LECTURE 8. Prof. Dr. Zafer ASLAN. LINEAR MAPPINGS. MAPPINGS Let A and B be arbitrary sets. Suppose to each a A there is assigned a unique element of B; the collection, f, of such assignments is called a function or mapping (or: map) from A into B, and is written

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Chapter 6- LINEAR MAPPINGS LECTURE 8

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  1. Chapter 6- LINEAR MAPPINGS LECTURE 8 Prof. Dr. Zafer ASLAN

  2. LINEAR MAPPINGS MAPPINGS Let A and B be arbitrary sets. Suppose to each aA there is assigned a unique element of B; the collection, f, of such assignments is called a function or mapping (or: map) from A into B, and is written f: A B or a f B We write f(a), read “f of a”, for the element of B that f assigns to aA; it is called the value of f at a or the image of a under f. If A’ is any subset of A, then f(A’) denotes the set of images of elements of A’; and if B’ is anysubset of A, then f(A’) denotes the set of images of elements of A’; and if B’ is any subset of B, then f-1(B’) denotes the set of elements of A each of qhose image lies in B’: f(A’) = {f(a): aA’} and f-1(B’) = {aA: f(a)B’}

  3. LINEAR MAPPINGS MAPPINGS We call f(A’) the image of A’ and f-1(B’) the inverse image or preimage of B’. In particular, the set of all images, i.e. F(A), is called the image ( or: range) of f. Furthermore A is called the domain of the mapping f: A B, and B is called its co-domain. To each mapping f: A B there corresponds the subset of AxB given by {(a,f(a)): aA}. We call this set the graph of f.

  4. LINEAR MAPPINGS THEOREM 6.1: Let f: A B, g: B C and h: C D. Then ho(gof) = (hog)of. We prove this theorem now. If aA, then (ho(gof))(a) = h((gof)(a))=h(g(f(a))) and ((hog)of)(a) = (gog)(f(a))= h(g(f(a))) Thus (ho(gof)(a) = ((gog)of(a) for every aA, and so ho(gof)=(hog)of

  5. LINEAR MAPPINGS Definition: A mapping f: A B, is said to be one –to-one ( or one – one or 1-1) or injective if different elements of A have distinct images; that is, if aa’ implies f(a)f(a’) or, equivalently, f(a) = f(A’) implies a=a’ A mapping f: A B is said to be onto (or: f maps A onto B) or surfective if every b B is the image of at least one aA.

  6. LINEAR MAPPINGS Let V and U be vector spaces over the same field K. A mapping F:V U is called a linear mapping ( or linear transformation or vector space homomorphism) if it satisfies the following two conditions: (1) For any v,w V, F (v+w) = F(v) + F(w). (2) For any kK and any vV, F(kv) = kF(v). In other words F: V U is linear if it “ preserves “ the two basic operations f a vector space, that of vector addition and that of scalar multiplication. Substituting k = 0 into (2) we obtain F(0). That is, every linear mapping takes the zero vector into the zero vector. Substituting k = 0 into (2) we obtain F(0)=0. That is, every linear mapping takes the zero vector into the zero vector.

  7. LINEAR MAPPINGS Definition: A linear mapping F: V U is called an isomorphism if it is one – to – one. The vector spaces V, U are said to be isomorphic if there is an isomorphism of V onto U. THEOREM 6.2: Let V and B vector spaces over a field K. Let {v1, v2, ..., vn} be a basis of V and u1, u2, ..., un be any vectors in U. Then there exists a unique linear mapping F: V U such that F(v1) = u1, F(v2) = u2, ..., F(vn) = un. We emphasize that the vectors u1, ..., un in the preceding theorem are completely arbitrary; they may be linearly dependent or they may even be equal to each other.

  8. LINEAR MAPPINGS THEOREM 6.4: Let V be of finite dimension and let F: V U be a linear mapping. Then dim V =dim (Ker F) + dim(Im F) That is, the sum of the dimensions of the image and kernel of a linear mapping is equal to the dimension of its domain. This formula is easily seen to hold for the projection mapping F. Remark: Let F: V U be a linear mapping. Then the rank of F is defined to be the dimension of its image, and the nullity of F is defined to be the dimension of its kernel: rank (F) = dim(ImF) and nullity (F) = dim(Ker F) Thus the preceding theorem yields the following formula for F then V has finite dimension: rank(F) + nullity (F) = dimV

  9. LINEAR MAPPINGS THEOREM 6.5: A linear mapping F: V U is an isomorphism if and only if it is non singular. We remark that nonsingular mappings can also be characterized as those mappings which carry independent sets into independent sets.

  10. LINEAR MAPPINGS LINEAR MAPPINGS AND SYSTEMS OF LINEAR EQUATIONS Consider a system of m linear equations in n unknowns over a filed K: a11x1 + a12x2 + ... + a1nxn = b1 a21x1 + a22x2 + ....+ a2nxn = b2 ................................................ am1x1+ am2x2+ ....+ amnxn = bm which is equivalent to the matrix equation. Ax = b where A =(aij) is the coefficient matrix, and (x = xi) and b = ( bi) are the column vectors of the unknowns and the constants, respectively. Now the matrix A may also be viewed as the linear mapping A: Kn Km

  11. LINEAR MAPPINGS THEOREM 6.6: Let V and U be vector spaces over a filed K. Then the collection of all linear mapping from V into U with the operations of addition and scalar multiplication form a vector space over K. The space in the above theorem is usually denoted by Hom (V,U) Here Hom comes from the word homomorphism. In the case that V and U are of finite dimension, we have the following theorem.

  12. LINEAR MAPPINGS THEOREM 6.7: Suppose dim V = m and dim U = n. Then dim Hom(V,U) = mn. Now suppose that V, U and W are vector spaces over the same field K, and that F: V U and G: U W are linear mappings: r G V U W

  13. LINEAR MAPPINGS THEOREM 6.8: Let V, U and W be vector spaces over K. Let F, F’ be linear mappings from V into U and G, G’ linear mappings from U into W, and let kK. Then: (i) F(G+H) = FG + FH (ii) (G+H)F = GF + HF (iii) k(GF) = (kG)F = G (kF). If the associative law also holds for the multiplication, i.e. İf for every F,G, H A, (iv) (FG)H = F(GH).

  14. LINEAR MAPPINGS INVERTIBLE OPERATORS A linear operator T: V V is said to be invertible if it has an inverse, i.e. İf here exists T-1 A(V) such that TT-1=T-1T = 1 Now T is invertible if and only if it is one-one and onto. Thus in particular, if T is invertible then ony 0V can map into itself, i.e. T is nonsingular. On the other hand, suppose T is nonsingular, i.e. Ker T = {0}. Recall that T is also one-one. Moreover, assuming V ahs finite dimension, we have by Theorem 6.4, dim V = dim (ImT ) + dim (Ker T) = dim(Im T)+dim({0}) =dim(ImT)+0=dim(ImT) Then ImT = V, i.e. The image of T is V; thus T is onto. Hence T is both one-one and onto and so is invertible. We have jist proven.

  15. LINEAR MAPPINGS THEOREM 6.9: A linear operator T: V V on a vector space of finite dimension is invertible if and only if it is nonsingular.

  16. LINEAR MAPPINGS THEOREM 6.10: Consider the following system of linear equations: a11x1 + a12x2 + ... + a1nxn = b1 a21x1 + a22x2 + ....+ a2nxn = b2 ................................................ am1x1+ am2x2+ ....+ amnxn = bm (i) If the corresponding homogeneous system has only the zero solution, then the above system has a unique solution for any values of the bi. (ii) If the corresponding homogeneous system has a nonzero solution, then: (i) there are values for the bi for which the above system does not have a solution; (ii) whenever a solution of the above system exists, it is not unique.

  17. Next Lecture (Week 8-9) Chapter 7:MATRICES AND LINEAR OPERATORS Reference Seymour LIPSCHUTZ, (1987): Schaum’s Outline of Theory and Problems of LINEAR ALGEBRA, SI (Metric) Edition, ISBN: 0-07-099012-3, pp. 334, McGraw – Hill Book Co., Singapore.

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