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In mathematics, notion of limit for sequences of sets
In mathematics, the limit of a sequence of sets (subsets of a common set ) is a set whose elements are determined by the sequence in either of two equivalent ways: (1) by upper and lower bounds on the sequence that converge monotonically to the same set (analogous to convergence of real-valued sequences) and (2) by convergence of a sequence of indicator functions which are themselves real-valued. As is the case with sequences of other objects, convergence is not necessary or even usual.
More generally, again analogous to real-valued sequences, the less restrictive limit infimum and limit supremum of a set sequence always exist and can be used to determine convergence: the limit exists if the limit infimum and limit supremum are identical. (See below). Such set limits are essential in measure theory and probability.
It is a common misconception that the limits infimum and supremum described here involve sets of accumulation points, that is, sets of where each is in some This is only true if convergence is determined by the discrete metric (that is, if there is such that for all ). This article is restricted to that situation as it is the only one relevant for measure theory and probability. See the examples below. (On the other hand, there are more general topological notions of set convergence that do involve accumulation points under different metrics or topologies.)
Definitions
The two definitions
Suppose that is a sequence of sets. The two equivalent definitions are as follows.
Using union and intersection: define[1][2] and If these two sets are equal, then the set-theoretic limit of the sequence exists and is equal to that common set. Either set as described above can be used to get the limit, and there may be other means to get the limit as well.
Using indicator functions: let equal if and otherwise. Define[1] and where the expressions inside the brackets on the right are, respectively, the limit infimum and limit supremum of the real-valued sequence Again, if these two sets are equal, then the set-theoretic limit of the sequence exists and is equal to that common set, and either set as described above can be used to get the limit.
To see the equivalence of the definitions, consider the limit infimum. The use of De Morgan's law below explains why this suffices for the limit supremum. Since indicator functions take only values and if and only if takes value only finitely many times. Equivalently,
if and only if there exists such that the element is in for every which is to say if and only if for only finitely many
Therefore, is in the if and only if is in all but finitely many For this reason, a shorthand phrase for the limit infimum is " is in all but finitely often", typically expressed by writing " a.b.f.o.".
Similarly, an element is in the limit supremum if, no matter how large is, there exists such that the element is in That is, is in the limit supremum if and only if is in infinitely many For this reason, a shorthand phrase for the limit supremum is " is in infinitely often", typically expressed by writing " i.o.".
To put it another way, the limit infimum consists of elements that "eventually stay forever" (are in each set after some), while the limit supremum consists of elements that "never leave forever" (are in some set after each). Or more formally:
for every there is a with for all and
for every there is a with for all .
Monotone sequences
The sequence is said to be nonincreasing if for each and nondecreasing if for each In each of these cases the set limit exists. Consider, for example, a nonincreasing sequence Then
From these it follows that
Similarly, if is nondecreasing then
If the limit of as goes to infinity, exists for all then Otherwise, the limit for does not exist.
It can be shown that the limit infimum is contained in the limit supremum: for example, simply by observing that all but finitely often implies infinitely often.
From the second definition above and the definitions for limit infimum and limit supremum of a real-valued sequence, and
Suppose is a 𝜎-algebra of subsets of That is, is nonempty and is closed under complement and under unions and intersections of countably many sets. Then, by the first definition above, if each then both and are elements of
Examples
Let Then
and
so exists.
Change the previous example to Then
and
so does not exist, despite the fact that the left and right endpoints of the intervals converge to 0 and 1, respectively.
Let Then
is the set of all rational numbers between 0 and 1 (inclusive), since even for and is an element of the above. Therefore,
On the other hand, which implies
In this case, the sequence does not have a limit. Note that is not the set of accumulation points, which would be the entire interval (according to the usual Euclidean metric).
Probability uses
Set limits, particularly the limit infimum and the limit supremum, are essential for probability and measure theory. Such limits are used to calculate (or prove) the probabilities and measures of other, more purposeful, sets. For the following, is a probability space, which means is a σ-algebra of subsets of and is a probability measure defined on that σ-algebra. Sets in the σ-algebra are known as events.
In probability, the two Borel–Cantelli lemmas can be useful for showing that the limsup of a sequence of events has probability equal to 1 or to 0. The statement of the first (original) Borel–Cantelli lemma is
First Borel–Cantelli lemma — If then
The second Borel–Cantelli lemma is a partial converse:
Second Borel–Cantelli lemma — If are independent events and then
Almost sure convergence
One of the most important applications to probability is for demonstrating the almost sure convergence of a sequence of random variables. The event that a sequence of random variables converges to another random variable is formally expressed as It would be a mistake, however, to write this simply as a limsup of events. That is, this is not the event ! Instead, the complement of the event is
Therefore,