Necessary Aand Sufficient Characterization Of Absolutely Continuous Functions Defined Over Unbounded Intervals
Abstract
In this paper, we investigate and find a necessary and sufficient condition for a function to be absolutely continuous over R (denoted by AC(R)) or any unbounded interval in R . Note that the Lebesgue's Fundamental theorem of Calculus gives us a necessary and sufficient conditionbook:B for a function defined over a closed interval [a,b] to be absolutely continuous ,and the condition is that the derivative of the function should be in L1loc([a,b]). However, we don't have any such sufficient condition on the derivative of a function that is absolutely continuous over unbounded intervals. One necessary condition is that the function must be locally absolutely continuous (denoted by ACloc(R)), but it may not be globally absolutely continuous despite being locally absolutely continuous(we give an explicit example of this). \\ The theorem 1 in this paper gives us a necessary and sufficient condition for a function belonging in ACloc(R) to belong in AC(R) in terms of its derivative and identifies the space to which the derivative of an AC(R) function must belong to as L1G(R) (a strict subspace of L1(R)). \\ Moreover, we define a new space of functions called L1H(R), and in theorem 2 we show that L1G ⊂ L1H, which helps us to find an easier criteria to check whether a function belonging to ACloc(R), belongs to AC(R) or not. \\ Finally, we provide a Venn diagram to explicitly show the relation of the newly defined spaces L1G(R) and L1H(R) with respect to the spaces L1loc(R), L1(R) and L∞(R).
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