1. An (infinite) sequence of real numbers may be viewed as a mapping of natural numbers into real numbers 0 a3a3 a1a1 a2a2 sometimes denotedor just

2. For a given sequence, we say that almost all of its terms have a property P if an index N exists such that a n has the property P whenever n >N. For example allmost all of the terms of the sequence are less than 0.000 000 000 000 000 000 000 000 000 000 001

3. Constant sequence a

4. Arithmetic sequence dddd a1a1 a2a2 a3a3 a4a4 a n-1 anan

5. Geometric sequence GDAEB a fifth the quotient in a fifth is q = 3:2

6. MarchApril May June A+B C+D July C+D E+F C+D A+B E+F G+H I+J In 1202 the mathematician Leonardo of Pisa, also called Fibonacci, published an influential treatise, Liber abaci. It contained the following recreational problem: "How many pairs of rabbits can be produced from a single pair in one year if it is assumed that every month each pair begets a new pair which from the second month becomes productive?"

7. The preceding example has shown that a sequence may also be defined using recurrence formulas, that is, defining the first few terms of the sequence and then giving a formula expressing the n-th sequence term through some of the preceeding terms. The Fibonacci “rabit-pair” sequence might be defined as follows: Explicit formulas may also be found equivalent to the recursive definition

9. (strictly) increasing sequence non-decreasing sequence (strictly) decreasing sequence non-increasing sequence

10. sequence bounded above with a as an upper bound sequence bounded below with b as a lower bound bounded sequence

11. by discarding some of its terms while still leaving an infinite number of them. Subsequence Let be a sequence and let be an increasing sequence of natural numbers (indices). Then we have sequence, which is called a subsequence of. Sometimes is said to be selected from

12. A sequence is bounded iff the sequence is bounded for an arbitrary positive integer k always exist

13. The limit of a sequence We say that a sequence has a limit A, formally if, for every, there exists N such that for every n > N

14. Examples strictly speaking, no limit exists, but in this case, sometimes  is taken to be one no limit exists

15. Every sequence has at most one limit

16. Rules for calculating limits of sequences: provided that both limits on the right-hand sides exist

17. If and for every n > N, then "squeezing rule"

18. If a sequence is bounded above and non-decreasing, it has a limit If a sequence is bounded below and non-increasing, it has a limit

19. Let be a sequence and let Let be an arbitrary subsequence of, then has a limit and

20. Point of condensation Let be a sequence. We say that a is a point of condensation of if, for every, we have for an infinite number of indices Let be a sequence. We say that a is a point of condensation of if, for every, and for every index N, there exists an index n > N such that

21. Example It is easy to see that the points of condensation of the above sequence are the numbers

22. Every bounded sequence has at least one point of condensation. From every bounded sequence, we can select a subsequence that is convergent. The set of all the points of condensation of a sequence has the least and the greatest element.

23. The greatest point u of condensation of a sequence is called an upper limit of (or a limes superior). The lowest point l of condensation of a sequence is called a lower limit of (or a limes inferior).

24. Example