In calculus and real analysis, absolute continuity is a smoothness property of functions that is stronger than continuity and uniform continuity. The notion of absolute continuity allows one to obtain generalizations of the relationship between the two central operations of calculus—differentiation and integration. This relationship is commonly characterized (by the fundamental theorem of calculus) in the framework of Riemann integration, but with absolute continuity it may be formulated in terms of Lebesgue integration. For real-valued functions on the real line, two interrelated notions appear: absolute continuity of functions and absolute continuity of measures. These two notions are generalized in different directions. The usual derivative of a function is related to the Radon–Nikodym derivative, or density, of a measure. We have the following chains of inclusions for functions over a compact subset of the real line:
- absolutely continuous ⊆ uniformly continuous continuous
and, for a compact interval,
- continuously differentiable ⊆ Lipschitz continuous ⊆ absolutely continuous ⊆ bounded variation ⊆ differentiable almost everywhere.
Absolute continuity of functions
editA continuous function fails to be absolutely continuous if it fails to be uniformly continuous, which can happen if the domain of the function is not compact – examples are tan(x) over [0,
Definition
editLet be an interval in the real line . A function is absolutely continuous on if for every positive number , there is a positive number such that whenever a finite sequence of pairwise disjoint sub-intervals of with satisfies[1]
then
The collection of all absolutely continuous functions on is denoted .
Equivalent definitions
editThe following conditions on a real-valued function f on a compact interval [a,b] are equivalent:[2]
- f is absolutely continuous;
- f has a derivative f ′ almost everywhere, the derivative is Lebesgue integrable, and for all x on [a,b];
- there exists a Lebesgue integrable function g on [a,b] such that for all x in [a,b].
If these equivalent conditions are satisfied, then necessarily any function g as in condition 3. satisfies g = f ′ almost everywhere.
Equivalence between (1) and (3) is known as the fundamental theorem of Lebesgue integral calculus, due to Lebesgue.[3]
For an equivalent definition in terms of measures see the section Relation between the two notions of absolute continuity.
Properties
edit- The sum and difference of two absolutely continuous functions are also absolutely continuous. If the two functions are defined on a bounded closed interval, then their product is also absolutely continuous.[4]
- If an absolutely continuous function is defined on a bounded closed interval and is nowhere zero then its reciprocal is absolutely continuous.[5]
- Every absolutely continuous function (over a compact interval) is uniformly continuous and, therefore, continuous. Every (globally) Lipschitz-continuous function is absolutely continuous.[6]
- If f: [a,b] → R is absolutely continuous, then it is of bounded variation on [a,b].[7]
- If f: [a,b] → R is absolutely continuous, then it can be written as the difference of two monotonic nondecreasing absolutely continuous functions on [a,b].
- If f: [a,b] → R is absolutely continuous, then it has the Luzin N property (that is, for any such that , it holds that , where stands for the Lebesgue measure on R).
- f: I → R is absolutely continuous if and only if it is continuous, is of bounded variation and has the Luzin N property. This statement is also known as the Banach-Zareckiǐ theorem.[8]
- If f: I → R is absolutely continuous and g: R → R is globally Lipschitz-continuous, then the composition g ∘ f is absolutely continuous. Conversely, for every function g that is not globally Lipschitz continuous there exists an absolutely continuous function f such that g ∘ f is not absolutely continuous.[9]
Examples
editThe following functions are uniformly continuous but not absolutely continuous:
- The Cantor function on [0, 1] (it is of bounded variation but not absolutely continuous);
- The function: on a finite interval containing the origin.
The following functions are absolutely continuous but not
- The function f(x) = x
β on [0, c], for any 0 <β <α < 1
The following functions are absolutely continuous and
- The function f(x) = √x on [0, c], for
α ≤ 1/2.
Generalizations
editLet (X, d) be a metric space and let I be an interval in the real line R. A function f: I → X is absolutely continuous on I if for every positive number , there is a positive number such that whenever a finite sequence of pairwise disjoint sub-intervals [xk, yk] of I satisfies:
then:
The collection of all absolutely continuous functions from I into X is denoted AC(I; X).
A further generalization is the space ACp(I; X) of curves f: I → X such that:[10]
for some m in the Lp space Lp(I).
Properties of these generalizations
edit- Every absolutely continuous function (over a compact interval) is uniformly continuous and, therefore, continuous. Every Lipschitz-continuous function is absolutely continuous.
- If f: [a,b] → X is absolutely continuous, then it is of bounded variation on [a,b].
- For f ∈ ACp(I; X), the metric derivative of f exists for
λ -almost all times in I, and the metric derivative is the smallest m ∈ Lp(I; R) such that:[11]
Absolute continuity of measures
editDefinition
editA measure on Borel subsets of the real line is absolutely continuous with respect to the Lebesgue measure if for every -measurable set implies . Equivalently, implies . This condition is written as We say is dominated by
In most applications, if a measure on the real line is simply said to be absolutely continuous — without specifying with respect to which other measure it is absolutely continuous — then absolute continuity with respect to the Lebesgue measure is meant.
The same principle holds for measures on Borel subsets of
Equivalent definitions
editThe following conditions on a finite measure on Borel subsets of the real line are equivalent:[12]
- is absolutely continuous;
- For every positive number there is a positive number such that for all Borel sets of Lebesgue measure less than
- There exists a Lebesgue integrable function on the real line such that: for all Borel subsets of the real line.
For an equivalent definition in terms of functions see the section Relation between the two notions of absolute continuity.
Any other function satisfying (3) is equal to almost everywhere. Such a function is called Radon–Nikodym derivative, or density, of the absolutely continuous measure
Equivalence between (1), (2) and (3) holds also in for all
Thus, the absolutely continuous measures on are precisely those that have densities; as a special case, the absolutely continuous probability measures are precisely the ones that have probability density functions.
Generalizations
editIf and are two measures on the same measurable space is said to be absolutely continuous with respect to if for every set for which [13] This is written as " ". That is:
When then is said to be dominating
Absolute continuity of measures is reflexive and transitive, but is not antisymmetric, so it is a preorder rather than a partial order. Instead, if and the measures and are said to be equivalent. Thus absolute continuity induces a partial ordering of such equivalence classes.
If is a signed or complex measure, it is said that is absolutely continuous with respect to if its variation satisfies equivalently, if every set for which is -null.
The Radon–Nikodym theorem[14] states that if is absolutely continuous with respect to and both measures are
Singular measures
editVia Lebesgue's decomposition theorem,[15] every
Relation between the two notions of absolute continuity
editA finite measure
is an absolutely continuous real function. More generally, a function is locally (meaning on every bounded interval) absolutely continuous if and only if its distributional derivative is a measure that is absolutely continuous with respect to the Lebesgue measure.
If absolute continuity holds then the Radon–Nikodym derivative of
More generally, the measure
Notes
edit- ^ Royden 1988, Sect. 5.4, page 108; Nielsen 1997, Definition 15.6 on page 251; Athreya & Lahiri 2006, Definitions 4.4.1, 4.4.2 on pages 128,129. The interval is assumed to be bounded and closed in the former two books but not the latter book.
- ^ Nielsen 1997, Theorem 20.8 on page 354; also Royden 1988, Sect. 5.4, page 110 and Athreya & Lahiri 2006, Theorems 4.4.1, 4.4.2 on pages 129,130.
- ^ Athreya & Lahiri 2006, before Theorem 4.4.1 on page 129.
- ^ Royden 1988, Problem 5.14(a,b) on page 111.
- ^ Royden 1988, Problem 5.14(c) on page 111.
- ^ Royden 1988, Problem 5.20(a) on page 112.
- ^ Royden 1988, Lemma 5.11 on page 108.
- ^ Bruckner, Bruckner & Thomson 1997, Theorem 7.11.
- ^ Fichtenholz 1923.
- ^ Ambrosio, Gigli & Savaré 2005, Definition 1.1.1 on page 23
- ^ Ambrosio, Gigli & Savaré 2005, Theorem 1.1.2 on page 24
- ^ Equivalence between (1) and (2) is a special case of Nielsen 1997, Proposition 15.5 on page 251 (fails for
σ -finite measures); equivalence between (1) and (3) is a special case of the Radon–Nikodym theorem, see Nielsen 1997, Theorem 15.4 on page 251 or Athreya & Lahiri 2006, Item (ii) of Theorem 4.1.1 on page 115 (still holds forσ -finite measures). - ^ Nielsen 1997, Definition 15.3 on page 250; Royden 1988, Sect. 11.6, page 276; Athreya & Lahiri 2006, Definition 4.1.1 on page 113.
- ^ Royden 1988, Theorem 11.23 on page 276; Nielsen 1997, Theorem 15.4 on page 251; Athreya & Lahiri 2006, Item (ii) of Theorem 4.1.1 on page 115.
- ^ Royden 1988, Proposition 11.24 on page 278; Nielsen 1997, Theorem 15.14 on page 262; Athreya & Lahiri 2006, Item (i) of Theorem 4.1.1 on page 115.
- ^ Royden 1988, Problem 12.17(b) on page 303.
- ^ Athreya & Lahiri 2006, Sect. 1.3.2, page 26.
- ^ Nielsen 1997, Proposition 15.7 on page 252; Athreya & Lahiri 2006, Theorem 4.4.3 on page 131; Royden 1988, Problem 12.17(a) on page 303.
References
edit- Ambrosio, Luigi; Gigli, Nicola; Savaré, Giuseppe (2005), Gradient Flows in Metric Spaces and in the Space of Probability Measures, ETH Zürich, Birkhäuser Verlag, Basel, ISBN 3-7643-2428-7
- Athreya, Krishna B.; Lahiri, Soumendra N. (2006), Measure theory and probability theory, Springer, ISBN 0-387-32903-X
- Bruckner, A. M.; Bruckner, J. B.; Thomson, B. S. (1997), Real Analysis, Prentice Hall, ISBN 0-134-58886-X
- Fichtenholz, Grigorii (1923). "Note sur les fonctions absolument continues". Matematicheskii Sbornik. 31 (2): 286–295.
- Leoni, Giovanni (2009), A First Course in Sobolev Spaces, Graduate Studies in Mathematics, American Mathematical Society, pp. xvi+607 ISBN 978-0-8218-4768-8, MR2527916, Zbl 1180.46001, MAA
- Nielsen, Ole A. (1997), An introduction to integration and measure theory, Wiley-Interscience, ISBN 0-471-59518-7
- Royden, H.L. (1988), Real Analysis (third ed.), Collier Macmillan, ISBN 0-02-404151-3