| Number of terms | Terms to be taken |
| 3 | \[ad,a,a+d\] |
| 4 | more...
The sum of n terms of the series
\[a+(a+d)+(a+2d)+.......+\{a+(n-1)\,d\}\] is given by
\[{{S}_{n}}=\frac{n}{2}[2a+(n-1)\,d]\]
Also, \[{{S}_{n}}=\frac{n}{2}(a+l)\], where \[l=\] last term \[=a+(n-1)d\].
If \[a,A,b\] are in A.P., then A is called A.M. between \[a\] and \[b\].
(1) If \[a,\,{{A}_{1}},\,{{A}_{2}},\,{{A}_{3}},.....,\,{{A}_{n}},\,b\] are in A.P., then \[{{A}_{1}},\,{{A}_{2}},\,{{A}_{3}},\,......,\,{{A}_{n}}\] are called \[n\] A.M.?s between \[a\] and \[b\].
(2) Insertion of arithmetic means
(i) Single A.M. between \[a\] and \[b\] : If \[a\] and \[b\] are two real numbers then single A.M. between \[a\] and \[b\]\[=\frac{a+b}{2}\]
(ii) n A.M.?s between a and b : If \[{{A}_{1}},\,{{A}_{2}},\,{{A}_{3}},\,.......,\,{{A}_{n}}\] are n A.M.?s between \[a\] and \[b\], then
\[{{A}_{1}}=a+d=a+\frac{b-a}{n+1}\], \[{{A}_{2}}=a+2d=a+2\frac{b-a}{n+1}\],
\[{{A}_{3}}=a+3d=a+3\frac{b-a}{n+1}\], ??., \[{{A}_{n}}=a+nd=a+n\frac{b-a}{n+1}\].
(1) If \[{{a}_{1}},\,{{a}_{2}},\,{{a}_{3}}.....\] are in A.P. whose common difference is \[d,\] then for fixed non-zero number \[k\in R\].
(i) \[{{a}_{1}}\pm k,\,{{a}_{2}}\pm k,\,{{a}_{3}}\pm k,.....\] will be in A.P., whose common difference will be \[d\].
(ii) \[k{{a}_{1}},\,k{{a}_{2}},\,k{{a}_{3}}....\] will be in A.P. with common difference \[=kd\].
(iii) \[\frac{{{a}_{1}}}{k},\,\frac{{{a}_{2}}}{k},\,\frac{{{a}_{3}}}{k}......\] will be in A.P. with common difference \[=d/k\].
(2) The sum of terms of an A.P. equidistant from the beginning and the end is constant and is equal to sum of first and last term. i.e. \[{{a}_{1}}+{{a}_{n}}={{a}_{2}}+{{a}_{n-1}}={{a}_{3}}+{{a}_{n-2}}=....\]
(3) If number of terms of any A.P. is odd, then sum of the terms is equal to product of middle term and number of terms.
(4) If number of terms of any A.P. is even then A.M. of middle two terms is A.M. of first and last term.
(5) If the number of terms of an A.P. is odd more...
A progression is called a G.P. if the ratio of its each term to its previous term is always constant. This constant ratio is called its common ratio and it is generally denoted by \[r\].
Example: The sequence 4, 12, 36, 108, ?.. is a G.P., because \[\frac{12}{4}=\frac{36}{12}=\frac{108}{36}=.....=3\], which is constant.
Clearly, this sequence is a G.P. with first term 4 and common ratio 3.
The sequence \[\frac{1}{3},\,-\frac{1}{2},\,\frac{3}{4},\,-\frac{9}{8},\,....\] is a G.P. with first term \[\frac{1}{3}\] and common ratio \[{\left( -\frac{1}{2} \right)}/{\left( \frac{1}{3} \right)=-\frac{3}{2}}\;\].
(1) We know that, \[a,\,ar,\,a{{r}^{2}},\,a{{r}^{3}},\,.....a{{r}^{n-1}}\] is a sequence of G.P.
Here, the first term is ‘a’ and the common ratio is \['r'\].
The general term or \[{{n}^{th}}\] term of a G.P. is \[{{T}_{n}}=a{{r}^{n-1}}\].
It should be noted that, \[r=\frac{{{T}_{2}}}{{{T}_{1}}}=\frac{{{T}_{3}}}{{{T}_{2}}}=......\].
(2) \[{{p}^{th}}\] term from the end of a finite G.P. : If G.P. consists of \['n'\] terms, \[{{p}^{th}}\] term from the end \[={{(n-p+1)}^{th}}\] term from the beginning \[=a{{r}^{n-p}}\].
Also, the \[{{p}^{th}}\] term from the end of a G.P. with last term \[l\]and common ratio \[r\] is \[l\,{{\left( \frac{1}{r} \right)}^{n-1}}\].
(1) When the product is given, the following way is adopted in selecting certain number of terms :
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