Five Theorems on Splitting Subspaces and Projections in Banach Spaces and Applications to Topology and Analysis in Operators

Abstract

Let B(E,F) denote the set of all bounded linear operators from E into F, and B+(E,F) the set of double splitting operators in B(E,F). When both E,F are infinite dimensional , in B(E,F) there are not more elementary transformations in matrices so that lose the way to discuss the path connectedness of such sets in B+(E,F) as m,n=\T∈ B(E,F): N(T)=m<∞ \ and \ codimR(T)=n<∞\, Fk=\T∈ B(E,F): rank\, T =k<∞\, and so forth. In this paper we present five theorems on projections and splitting subspaces in Banach spaces instead of the elementary transformation. Let denote any one of Fk ,k<∞ and m,n with either m>0 or n>0. Using these theorems we prove is path connected.Also these theorems bear an equivalent relation in B+(E,F), so that the following general result follows: the equivalent class T generated by T∈ B+(E,F) with either N(T)>0 or codim R(T)>0 is path connected. (This equivalent relation in operator topology appears for the first time.) As applications of the theorems we give that is a smooth and path connected submanifold in B(E,F) with the tangent space TX =\T∈ B(E,F): TN(X)⊂ R(X)\ at any X∈ , and prove that B(Rm,Rn)=\n,m\k=0Fk possesses the following properties of geometric and topology : Fk ( k <\ m,n\) is a smooth and path connected subhypersurface in B(E,F), and specially, Fk=(m+n-k)k, k=0,1, ·s , \m.n\. Of special interest is the dimensional formula of Fk \, \, k=0,1, ·s , \m.n\, which is a new result in algebraic geometry. In view of the proofs of the above theorems it can not be too much to say that Theorems 1.1-1.5 provide the rules of finding path connected sets in B+(E,F).