This chapter is one of the main contents of the proposition of college entrance examination. We should review it comprehensively and deeply, and focus on solving the following problems on this basis: (1) The proof of arithmetic and geometric series must be proved by definition. It is worth noting that if the sum of the first few items of a series is given, the general items can be written if it is satisfied. (2) The calculation of series is the central content of this chapter. Using the general formula, antecedents, formulas and their properties of arithmetic progression and geometric progression to make clever calculations is the key content of the college entrance examination proposition. (3) When solving the problem of sequence, we often use various mathematical ideas. It is our goal to be good at using various mathematical ideas to solve the problem of sequence. (1) Function Thought: The summation formula of the general term formula of arithmetic geometric progression can be regarded as a function, so some problems of arithmetic geometric progression can be solved as function problems.

(2) The idea of classified discussion: the summation formula of equal proportion series should be divided and summed; When the time is known, it should also be classified;

③ Holistic thinking: When solving the sequence problem, we should pay attention to getting rid of the rigid thinking mode solved by formulas and use integers.

Body and mind solutions.

(4) When solving the related application problems of series, we should carefully analyze and abstract the actual problems into mathematical problems, and then use the knowledge and methods of series to solve them. Solving this kind of application problem is a comprehensive application of mathematical ability, and it is by no means a simple imitation and application. Pay special attention to the items of geometric series related to years.

First, the basic concept:

1, definition and representation of sequence:

2. Items and number of items in the series:

3, finite sequence and infinite sequence:

4, increasing (decreasing), swing, cycle order:

5. The general formula of sequence {an} an:

6. The first n terms of the sequence and the formula Sn:

7. Structure of arithmetic progression, Tolerance D and arithmetic progression:

8. The structure of geometric series, Bi Gong Q and geometric series;

Second, the basic formula:

9. the relationship between the general term an and the first n terms and Sn of a general sequence: an=

10, the general formula of arithmetic progression: an = a 1+(n-1) Dan = AK+(n-k) d (where a1is the first term and AK is the known k term), when d≠0.

1 1, the first n terms of arithmetic progression and its formula: Sn= Sn= Sn=

When d≠0, Sn is a quadratic form about n, and the constant term is 0; When d=0 (a 1≠0), Sn=na 1 is a proportional formula about n.

12, the general formula of geometric series: an = a1qn-1an = akqn-k.

(where a 1 is the first term, ak is the known k term, and an≠0).

13, the first n terms of geometric series and their formulas: when q= 1, Sn=n a 1 (this is a direct ratio formula about n);

When q≠ 1, Sn= Sn=

Third, the conclusion about arithmetic and geometric series.

Arithmetic progression {an} formed by the sum of any continuous m terms of Sm, S2m-Sm, S3m-S2m, S4m-S3m series, ... 14 is still arithmetic progression.

15, arithmetic progression {an}, if m+n=p+q, then

16, geometric series {an}, if m+n=p+q, then

Geometric progression {an} formed by the sum of any continuous m terms of Sm, S2m-Sm, S3m-S2m, S4m-S3m series, ... 17 is still geometric progression.

18, the sum and difference of two arithmetic progression {an} and {bn} series {an+bn} is still arithmetic progression.

19, a sequence consisting of the product, quotient and reciprocal of two geometric series {an} and {bn}

{an bn},,, or geometric series.

20. arithmetic progression {an} Any equidistant series is still arithmetic progression.

2 1, the series of any equidistant term of geometric progression {an} is still geometric progression.

22. How to make three numbers equal: A-D, A, A+D; How to make four numbers equal: A-3D, A-D, A+D, A+3D?

23. How to make three numbers equal: A/Q, A, AQ;

Wrong method of four numbers being equal: a/q3, a/q, aq, aq3 (Why? )

24.{an} is arithmetic progression, then (c>0) is a geometric series.

25 、{ bn }(bn & gt； 0) is a geometric series, then {logcbn} (c >; 0 and c 1) are arithmetic progression.

26. In the arithmetic series:

(1) If the number of items is, then

(2) If the quantity is,

27. In geometric series:

(1) If the number of items is, then

(2) If the number is 0,

Four, the common methods of sequence summation: formula method, split item elimination method, dislocation subtraction, reverse addition, etc. The key is to find the general item structure of the sequence.

28. Find the sum of series by grouping method: for example, an=2n+3n.

29. Sum by dislocation subtraction: for example, an=(2n- 1)2n.

30. Sum by split term method: for example, an= 1/n(n+ 1).

3 1, sum by addition in reverse order: for example, an=

32. The method of finding the maximum and minimum term of series {an}:

① an+ 1-an = ... For example, an= -2n2+29n-3.

② (An>0) as a =

③ an=f(n) Study the increase and decrease of function f(n), such as an=

33. In arithmetic progression, the problem about the maximum value of Sn is often solved by the adjacent term sign change method:

(1) When >: 0, d < When 0, the number of items m meets the maximum value.

(2) When