Exponential approximation in variable exponent Lebesgue spaces on the real line

Abstract

Present work contains a method to obtain Jackson and Stechkin type inequalities of approximation by integral functions of finite degree (IFFD) in some variable exponent Lebesgue space of real functions defined on R:=( -∞ ,+∞ ) . To do this we employ a transference theorem which produce norm inequalities starting from norm inequalities in C(R), the class of bounded uniformly continuous functions defined on R. Let B⊂eq R be a measurable set, p( x) :B→ 1,∞ ) be a measurable function. For the class of functions f belonging to variable exponent Lebesgue spaces Lp( x) (B) we consider difference operator ( I-Tδ ) rf( · ) under the condition that p(x) satisfies the Log H\"older continuity condition and 1≤ ess \; infx∈ Bp(x), ess \; supx∈ Bp(x)<∞ where I is the identity operator, r∈ N:=\ 1,2,3,·s \ , δ ≥ 0 and equation* Tδ f( x) =1δ ∫0δ f( x+t) dt ) equation* is the forward Steklov operator. We obtain main properties of difference operator ( I-Tδ ) rf p( · ) in Lp( x) ( B) . We give proof of direct and inverse theorems of approximation by IFFD in Lp( x) ( R).