A Note on Linear Homomorphisms. in R-Vector Spaces

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International Journal of Algebra, Vol. 5, 2011, no. 28, 1355-1362 A Note on Linear Homomorphisms in R-Vector Spaces K. Venkateswarlu Department of Mathematics, Addis Ababa University, Addis Ababa, Ethiopia drkvenky@yahoo.co.in N. Amarnath Department of Mathematics Praveenya Institute of Marine Engineering and Maritime Studies Modavalasa, Vizianagaram, AP, India amar_studies@yahoo.in Abstract In this paper we give necessary and sufficient condition for a linear transformation to be strongly linear. Further we prove that if G is a basis for V then T(G) is a basis for T(V) Mathematics Subject Classification. Primary 15A03, 16G30 Keywords: R-vector space, normed R-Vector space, basis, linear and strongly linear homomorphisms Introduction The concept of Bounded Boolean extension of an group is due to A.L.Foster[1]. He demonstrated that each element of a p-ring R with unity can be represented as a type of Boolean vector over the Boolean algebra of all the idempotent elements of R. Later Penning [4] and Zemmer [9] have simplified the proof of A. L. Foster concerning a basis consisting of non zero elements of the additive subgroup of R by

1356 K. Venkateswarlu and N. Amarnath its unity element. Subrahmanyam [ 5 ] motivated by the concept of A.L.Foster has introduced the notion of abstract vector space over a Boolean algebra ( simply Boolean vector space).in fact Boolean vector space is a natural generalization of this idea of A.L.Foster. The contribution of Subrahmanyam s work is in [ 5,6,7]. Later Raja Gopala rao [2] has generalized the concept of B-vector spaces to vector spaces over regular rings ( simply R-vector spaces). He studied several properties of these spaces in [ 2,3], generalizing the results of Subrahmanayam. Also Venkateswarlu [8] has introduced the concept of direct sums in R- vector spaces and ( n i has proved that G ) ) is a basis for V ) if V 1..V n are vector spaces over the i same regular ring R having bases G 1, G n respectively. ( n i In this paper we introduce the concept of strong linear homomorphism from an R- Vector space V into another R-Vector space W and give a necessary and sufficient condition of a linear homomorphism to be strongly linear homomorphism ( see theorem 2.5).Also we prove that G is a basis for V then T(G) is a basis for T(V) where T : V W is an isomorphism(see theorem 2.6) i 1. Preliminary Results We collect certain definitions and results concerning R-Vector spaces of Raja Gopala rao [2,3] Definition 1.1.A ring R is called a regular ring to each a R there is an element x R such that axa = a. If a R and a x a = a then we put a = xax For any a R, define norm of an element a which will be denoted by a, by putting a = a B denotes the set of all idempotent elements of regular ring R. Lemma 1.2. 1. a = a a B 2. If ab = 0 then b a = a b = a b =0 3. a a = a = a a 4. a (1 + a - a ) = a

Linear homomorphisms in R-vector spaces 1357 Let (V,+) be any group, R = (R, +,. ) be a commutative regular ring with unity element 1 B = (B,, ) denotes the Boolean algebra of idempotents of R ( for a,b B,a b = a + b - ab,a b = ab, a =1-a) and U denotes the multiplicative group of invertible elements of R Definition 1.3. V is said to be a vector space over R ( or an abstract R- vector space) if and only if there exists a mapping : R x V V ( the image of any (a,x) in R x V will be denoted by ax such that for all x,y V and a,b R, the following properties hold 1. a 2 (x + y) = ax + ay 2. a(bx) = (ab)x if a 2 = a 3. 1x = x 4. (a + b)x = ax + bx if ab = 0 5. r(sx)=(rs)x if r and s are invertible elements of R and 6. a0 = 0 implies a 2 = a We denote 0 element of R and 0 element of V as 0 Remark 1.4..Any R-vector space can be treated as a Boolean vector space ( simply B-vector space) where B is the Boolean algebra of idempotents of R with respect to the scalar multiplication as defined in R-vector space. Definition 1.5. A R- vector space V is said to be B-normed (or simply normed ) there exists a mapping norm. : V B satisfying the properties 1) x = 0 x = 0 2) ax = a x for all x V, a B Definition 1.6. A finite subset of nonzero elements x 1,x 2, x n of a R- vector space V, is called (linearly) independent over R a 1 x 1 + a 2 x 2 +..+ a n x n = 0 and a 1 a 2 a 3..a n 0 imply x 1 + x 2 +..+ x n and a subset S of non zero elements

1358 K. Venkateswarlu and N. Amarnath of V is said to be independent subset of V every finite subset of S of V is linearly independent over R Definition 1.7. I if S is a subset of V, we say S spans V each x V can be written as x = a g g S {0} all g S {0} and g where a g a h = 0 if g,h S {0} and g h, a g = 0 for almost a g g S {0} = 1 Definition1.8. An independent subset of V which spans V is called basis for V Theorem 1.9. G is a subgroup of V where G = G {0} Lemma 1.10. If g G and r U then r g =1 Theorem 1.11. The representation of each x V in terms of a basis group is unique. If G is a basic group for V then a x,g represents the uniquely determined coefficient of any g G in the representation of x in terms of G and x = g G a x, g g 2 Linear Homomorphisms of R vector spaces Raja gopala rao [2] introduced the concept of linear endomorphisms in R Vector Spaces. We consider the notion of linear Homomorphisms from one R- vector Space to another. Now we begin with the following Definition 2.1 Let V and W be R vector spaces over a regular ring R. A mapping T :V W is called linear homomorphism of V into W if for all x, y V and a, b R 1. T( ax + by) = a Tx + b T y if ab = 0 The set of linear homomorphisms will be denoted by Hom (V,W). Definition 2.2. Let V,W be R vector spaces. A mapping T : V W is called strongly linear homomorphism of V into W provided 2. T( ax + by) = a Tx + b T y for all x, y V and a, b R

Linear homomorphisms in R-vector spaces 1359 The set of all strongly linear homomorphisms will be denoted by Hom (V,W) Definition2.3. Let V,W be R vector spaces. A one to one mapping T from V onto W is called an isomorphism provided 1. T(x + y) = Tx + Ty 2. T(ax) = atx for a U Theorem.2.4. Let V and W be R- Vector spaces. A mapping T of V into W is an element of Hom (V,W) T( ax ) = a T(x) for all x V and a R Proof. : Let T Hom (V,W). If x V and a R then T(ax ) = T(ax + 0x) = atx + 0Tx = atx + 0 = atx : Let T(ax ) = atx.let x, y V and a, b R such that ab = 0 Consider T(ax + by ) = 1 T(ax + by ) = ( a +1 - a ) T(ax + by ) = a T(ax + by ) +(1 - a ) T(ax + by ) ( by 4 of def 1.3) = T( a ( ax + by )) + T((1 - a ) (ax + by )) = T( a (ax) + a (by )) + T((1 - a ) (ax) +(1 - a ) ( by ))) = T(( a a)x) +( a b)y )) + T(((1 - a )a)x) +((1 - a ) b)y ))) = T((ax) +0y ) + T(0x +(b -b a )y ) = T(ax) + T((b - 0)y ) = T(ax) + T(by ) = atx + bty Now we give a necessary and sufficient condition for linear transformation to be strongly linear in the following Theorem 2.5. LetV,W be R-vector spaces. Let T Hom (V,W).A necessary and sufficient condition for T is strongly linear is that T( x + y) = Tx + Ty for all x,y V Proof. Necessary condition follows by putting a = b =1 in definition 2.2

1360 K. Venkateswarlu and N. Amarnath For sufficiency, let T Hom (V, W) and x, y V. Then T(ax+by) = T(ax) + T(by) ( by hypothesis) = T[ a (a +1 - a )x + b (b +1 - b )y] = a T[ (a +1 - a )x + b T (b +1 - b )y = { a [(a +1 - a )}Tx + { b (b +1 - b )}Ty = a Tx + bty. Thus T is strongly linear homomorphism. Theorem2.6. Let V,W be R vector spaces,t is an isomorphism form V into W. If G is a Basis for V then T(G ) is a basis for T(V) Proof. Let G be a basis for V. Since 0 G, it is clear that 0 T(G ) Let x V. Then x a x, g g and a x, g a x,h = 0 for g h and a x,g = 0 for almost all g G Hence Tx = T ( Tg T ( G ) a x, g g ) ( T a x, g g ) T [ a x,g ( a x,g +1 - a x,g )g] ( by 4 of lemma 2) a x,g T [ (a x,g +1 - a x,g )g] a x,g ( a x,g +1 - a x,g )Tg (by def 2.3) a x,g Tg a x,g Tg Hence T(G ) spans T( V ) 2. Let Tg 1, Tg 2,.., Tg n T(G) and a 1 Tg 1 + a 2 Tg 2 + + a n Tg n = 0 and a 1, a 2,.,a n 0 for a 1, a 2,.,a n R.

Linear homomorphisms in R-vector spaces 1361 Then 0 = a 1 Tg 1 + a 2 Tg 2 +..+ a n Tg n = [ a 1 (a 1 +1 - a 1 )]T g 1 +.+ [ a n ( a n +1 - a n )] T g n = a 1 T [(a 1 +1 - a 1 ) g 1 ] +.+ a n T [(a n +1 - a n ) g n ] = T [ a 1 (a 1 +1 - a 1 ) g 1 ] +.+ T[ a n ( a n +1 - a n ) g n ] = T [a 1 g 1 ]+.+ T[a n g n ] = T (a 1 g 1 +.+ a n g n ) Now T(a 1 g 1 +.+ T a n g n ) = 0 = T0 a 1 g 1 +.+ a n g n = 0 (since T is one one ). Since G is linearly independent, we have that g 1 + g 2 +. + g n = 0 T(g 1 + g 2 +. + g n ) = T0 T(g 1 ) +T(g 2 ) +. +T(g n ) = 0. This shows that T(G) is linearly independent. Thus T (G) is a basis for T(V). = a T[ (a +1 - a )x + b T (b +1 - b )y = { a [(a +1 - a )}Tx + { b (b +1 - b )}Ty = a Tx + bty. References 1. Foster.A.L (1951) :. P-rings and their Boolean Vector Representation Acta Math,84, 231-261 2. N. Raja Gopala Rao. (1966): Vector Spaces over a regular ring,math.annelen, 280-291 3.N.Raja Gopala Rao (1968): On Regular rings, The Journal of Indian Society of Mathematics, Vol 10, No 2,95-100 4. Penning C.J,(1960) :Boolean Metric Spaces,Doctoral Thesis, Technische Hogeshool te delft

1362 K. Venkateswarlu and N. Amarnath 5. Subrahmanyam N.V (1964) : Boolean Vector Spaces- I, Math. Z. 83 pp 422-433 6. Subrahmanyam N.V (1965): Boolean Vector Spaces- II Math. Z. 87, pp 401-419 7. Subrahmanyam N.V (1967) : Boolean Vector Spaces- II Math. Z. 100 pp 295-313 8. Venkateswarlu.K (1995): Direct sum of R-vector spaces, SEA Bull. Math, Vol 19, No1, 27-30 9. Zemmer.J.L(1956). Some remarks on p-rings and their Boolean geometry, Pacific Journal of Mathematics -6, 193-208 Received: May, 2011

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