SEQUENCE AND SERIES
INTRODUCTION:
SEQUENCE: A sequence is a function whose domain is the set N of natural numbers.
REAL SEQUENCE: A sequence whose range is a subset of R is called a real sequence.
In other words,a real sequence is a function with domain N and the range a subset of the set R of real numbers.
SERIES:
SERIES:
If a1, a2, a3, a4, .... an is a sequence, then the expression
a1+ a2+a3+a4+a5+...+an+... is a series.
PROGRESSIONS:
It is not necessary that the terms of a sequence
always follow a certain pattern or they
are described by some explicit formula for the nth term. Those sequences
whose terms follow certain pattern are called progressions.
· Every Progression is a series but every Series need not be a Progression.
· They are 4 types of Progressions (mainly 3)
1) Arithmetic Progression
2) Geometric Progression
3) Harmonic Progression
4) Arithmetico-Geometric Progression
PROGRESSIONS:
It is not necessary that the terms of a sequence
always follow a certain pattern or they
are described by some explicit formula for the nth term. Those sequences
whose terms follow certain pattern are called progressions.
· Every Progression is a series but every Series need not be a Progression.
· They are 4 types of Progressions (mainly 3)
1) Arithmetic Progression
2) Geometric Progression
3) Harmonic Progression
4) Arithmetico-Geometric Progression
ARITHMETIC PROGRESSION (A.P.):
The constant difference, generally denoted by d is called the common difference.
ILLUSTRATION 1
If a is the first term and d the common difference of an A.P., then its nth terms an is given by
PROPERTY II:
A sequence is an A.P if its nth term is of the form case is An+ B i.e. a linear
expression in n. The common difference is such a case is A i.e. the coefficient
of n.
PROPERTY III:
for all k = 1 ,2 ,3 ,…, n-1.
PROPERTY VI:
If an, an+1 and an+2 three consecutive terms of an A.P., then.,
SELECTION OF TERMS IN AN A.P.
The following ways of selecting terms are generally very
convenient.
SOME USEFUL RESULTS
AN IMPORTANT PROPERTY:
A sequence is an A.P. if and only if the sum of its
n terms is of the form
where A, B are constants. In such a case, the common
difference of the A.P is 2A.
REMARK:
i.e., a quadratic expression in n and in such a case tehe common difference is twice the coefficient of n2. For example, if
we can say theat it is sum of n terms of an A.P with common difference 6.
INSERTION OF ARITHMETIC MEANS:
- If between two given quantities a and b we have to insert n quantities A1,A2,...An, such that A1,A2,...An, b form an A.P. Then we say that A1,A2,...An are arithmetic means between a and b.
- Example: Since 15,11,7,3,-1,-5 are in A.P.,it follows that 11,7,3,-1 are four arithmetic means between 15 and -5.
INSERTION OF n ARITHMETIC MEANS BETWEEN a AND b:
INSERTION OF A SINGLE ARITHMETIC MEAN BETWEEN a AND b:
Let A be the arithmetic mean of a and b. Then a,A,b are in A.P.
ARITHMETIC PROGRESSION (A.P.):
A sequence is
called an arithmetic progression if the difference of a term and the previous
term is always same i.e.
ILLUSTRATION 1
1,4,7,10,… is an A.P. whose first term is 1 and the
common difference is 4-1=3.
ILLUSTRATION
2
11 ,7,3,-1, … is an A.P. whose first term is 11 and
the common difference 7-11=-4.
PROPERTIES OF AN ARITHMETIC PROGRESSION:
PROPERTY I :
If a is the first term and d the common difference of an A.P., then its nth terms an is given by
PROPERTY II:
If a is the first term and d the common difference of an A.P., then its nth terms an is given by
A sequence is an A.P if its nth term is of the form case is An+ B i.e. a linear
expression in n. The common difference is such a case is A i.e. the coefficient
of n.
PROPERTY III:
If a constant is added to or subtracted from each
term of an A.P., then the resulting sequence is also an A.P. with the same
common difference.
PROPERTY IV:
If each term
of a given A.P. is multiplied or divided by a non-zero constant k, then the
resulting sequence is also an A.P. with
common difference kd or d/k , where d is the common difference of the
given AP.
PROPERTY V:
In a finite A.P. the sum of the terms equidistant
from the beginning and end is always same and is equal to the sum of first and
last term i.e.
for all k = 1 ,2 ,3 ,…, n-1.
PROPERTY VI:
Three numbers a,b,c are in A.P. if 2b =a+c.
PROPERTY VII:
If the terms of an A.P. are chosen at regular
intervals, then the form of an A.P.
PROPERTY VIII:
If an, an+1 and an+2 three consecutive terms of an A.P., then.,
SELECTION OF TERMS IN AN A.P.
If an, an+1 and an+2 three consecutive terms of an A.P., then.,
The following ways of selecting terms are generally very
convenient.
SOME USEFUL RESULTS
AN IMPORTANT PROPERTY:
A sequence is an A.P. if and only if the sum of its
n terms is of the form
where A, B are constants. In such a case, the common
difference of the A.P is 2A.
REMARK:
It follows from this
property that a sequence is an A.P. if the sum of its n terms is of the form
i.e., a quadratic expression in n and in such a case tehe common difference is twice the coefficient of n2. For example, if
we can say theat it is sum of n terms of an A.P with common difference 6.
INSERTION OF ARITHMETIC MEANS:
- If between two given quantities a and b we have to insert n quantities A1,A2,...An, such that A1,A2,...An, b form an A.P. Then we say that A1,A2,...An are arithmetic means between a and b.
- Example: Since 15,11,7,3,-1,-5 are in A.P.,it follows that 11,7,3,-1 are four arithmetic means between 15 and -5.
INSERTION OF n ARITHMETIC MEANS BETWEEN a AND b:
INSERTION OF A SINGLE ARITHMETIC MEAN BETWEEN a AND b:
Let A be the arithmetic mean of a and b. Then a,A,b are in A.P.
Let A be the arithmetic mean of a and b. Then a,A,b are in A.P.
No comments:
Post a Comment