Given a field of sets and a Banach space a finitely additive vector measure (or measure, for short) is a function such that for any two disjoint sets and in one has
A vector measure is called countably additive if for any sequence of disjoint sets in such that their union is in it holds that
with the series on the right-hand side convergent in the norm of the Banach space
It can be proved that an additive vector measure is countably additive if and only if for any sequence as above one has
Consider the field of sets made up of the interval together with the family of all Lebesgue measurable sets contained in this interval. For any such set define
where is the indicator function of Depending on where is declared to take values, two different outcomes are observed.
viewed as a function from to the -space is a vector measure which is not countably-additive.
viewed as a function from to the -space is a countably-additive vector measure.
Both of these statements follow quite easily from the criterion (*) stated above.
The variation of a vector measure
Given a vector measure the variation of is defined as
where the supremum is taken over all the partitions
of into a finite number of disjoint sets, for all in Here, is the norm on
The variation of is a finitely additive function taking values in It holds that
for any in If is finite, the measure is said to be of bounded variation. One can prove that if is a vector measure of bounded variation, then is countably additive if and only if is countably additive.
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^ abDiestel, Joe; Uhl, Jerry J. Jr. (1977). Vector measures. Providence, R.I: American Mathematical Society. ISBN0-8218-1515-6.
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The concept of a convex set (i.e., a set containing the segment connecting any two of its points) had repeatedly been placed at the center of economic theory before 1964. It appeared in a new light with the introduction of integration theory in the study of economic competition: If one associates with every agent of an economy an arbitrary set in the commodity space and if one averages those individual sets over a collection of insignificant agents, then the resulting set is necessarily convex. [Debreu appends this footnote: "On this direct consequence of a theorem of A. A. Lyapunov, see Vind (1964)."] But explanations of the ... functions of prices ... can be made to rest on the convexity of sets derived by that averaging process. Convexity in the commodity space obtained by aggregation over a collection of insignificant agents is an insight that economic theory owes ... to integration theory. [Italics added]
Debreu, Gérard (March 1991). "The Mathematization of economic theory". The American Economic Review. Vol. 81, number 1, no. Presidential address delivered at the 103rd meeting of the American Economic Association, 29 December 1990, Washington, DC. pp. 1–7. JSTOR2006785.
^Hermes, Henry; LaSalle, Joseph P. (1969). Functional analysis and time optimal control. Mathematics in Science and Engineering. Vol. 56. New York—London: Academic Press. pp. viii+136. MR0420366.
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^Tardella, Fabio (1990). "A new proof of the Lyapunov convexity theorem". SIAM Journal on Control and Optimization. 28 (2): 478–481. doi:10.1137/0328026. MR1040471.
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