Exercises
- Find
(a) the common ratio,
(b) the $10^{\text {th }}$ term and
(c) the $n^{\text {th }}$ term of the following G.P.
(i) $4,2,1, \dfrac{1}{2}, \ldots$
(ii) $-2,4,-8,16, \ldots$
(iii) $5,20,80,320, \ldots$
(iv) $\dfrac{1}{3},-\dfrac{1}{9}, \dfrac{1}{27},-\dfrac{1}{81}, \ldots$
(v) $\dfrac{8}{9}, \dfrac{4}{3}, 2,3, \ldots$
(vi) $x^{5}, x^{4} y, x^{3} y^{2}, x^{2} y^{3}, \ldots$ - If $3, x, y, z, w$ and 3072 are consecutive terms of a G.P., find the value of $x$, $y, z$ and $w$.
- The second term of a G.P. is 64 and the fifth term is 27 . Find the first 6 terms of the G.P.
- Find the $10^{\text {th }}$ term of the G.P. $a^{5}, a^{4} b, a^{3} b^{2}, a^{2} b^{3}, \ldots$. Which term of the G.P. is $\dfrac{b^{20}}{a^{15}} ?$
- The $4^{\text {th }}$ term of the G.P is 3 and the sixth term is 147 . Find the first three terms of the two possible geometric progressions.
- The product of the first three terms of the G.P. is 1 and the product of the third, fourth and the fifth term is $11 \dfrac{25}{64}$. Find the fifth term of the G.P.
- Find two different values of $x$, so that $-\dfrac{3}{2}, x,-\dfrac{8}{27}$ will be a G.P.
- Find which term of the G.P. $\dfrac{8}{9}$, $\dfrac{4}{3} \sqrt{\dfrac{2}{3}}$, $\dfrac{4}{3}, \ldots$ is $\sqrt{6}$.
- If $a, b, c, d$ is a G.P., show that $a^{2}-b^{2}$, $b^{2}-c^{2}$, $c^{2}-d^{2}$ is also a G.P.
- If $a, b, c, d$ is a G.P., show that
(i) $\dfrac{b+c}{c+d}=\dfrac{a+c}{b+d}$.
(ii) $(a+d)(b+c)-(a+c)(b+d)=(b-c)^{2}$. - If $a, b, c$ is an A.P. and $x, y, z$ is a G.P., show that $x^{b-c} y^{c-a} z^{a-b}=1$.
- In a G.P. the product of any three consecutive terms is $512$ . When 8 is added to the first term and $6$ to the second, then the terms form an A.P. Find the terms of the G.P.
- In a G.P. the product of any three consecutive terms is $216$ . When 1 is added to the first term and $2$ to the second, then the terms form an A.P. Find the terms of the G.P.
- $8, x, y$ are three consecutive terms of an A.P. while $x, y, 36$ are three consecutive terms of a G.P., find the possible values of $x$ and $y$.
- In a G.P., whose first term is positive, the sum of the first and the third term is $\dfrac{13}{9}$ and the product of the second and fourth term is $\dfrac{16}{81}$. Find the common ratio and the $6^{\text {th }}$ term.
- If $\log _{3} 2$, $\log _{4} x$, $\log _{2} 81$ is a G.P. then find the possible values of $x$.
- If $\dfrac{1}{b+a}, \dfrac{1}{2 b}$ and $\dfrac{1}{b+c}$ are in A.P., prove that $a, b$ and $c$ are in G.P.
- In a G.P., the first term exceeds the third term by $72$ and the sum of the second and third term is $36$ . Find the first term.
- The fourth term of a G.P. is $9$ and the ninth term is $2187$. Find the first 4 terms of the G.P.
- The fourth term of a G.P. exceeds the third by $\dfrac{3}{44}$ and the third term exceeds the second term by $\dfrac{1}{22}$. Find the first term and the sixth term of the G.P.
- Three consecutive terms of a G.P. are $3^{2 x-1}, 9^{x}$ and $243$ . Find the value of $x$. If $243$ is the fifth term of the G.P., find the seventh term.
- Find three numbers in a G.P. such that their sum is $42$ and their product is $512$.
- Insert two geometric means between $2$ and $128$ .
- The ratios of two numbers is $9: 1$. The sum of the arithmetic mean and geometric mean between the two numbers is $96$ , find the two numbers.
- If the arithmetic mean between $x$ and $y$ is $15$ and the geometric mean is $9$ , find $x$ and $y$.
- Show that the products of the corresponding terms of the sequences $a, a r, a r^{2}, \ldots, a r^{n-1}$ and $A, A R, A R^{2}, \ldots, A R^{n-1}$ form a G.P, and find the common ratio.
- Given that $\dfrac{a+b x}{a-b x}=\dfrac{b+c x}{b-c x}=\dfrac{c+d x}{c-d x}$ where $x \neq 0$, prove that $a, b, c, d$ are in G.P.
- If $a, b, c, d$ are in G.P., prove that $a+b, b+c$ and $c+d$ are also in G.P.
- If $a, b, c$ are in A.P., show that $2^{a x+1}$, $2^{b x+1}$, $2^{c x+1}$ are in G.P.
- The first three terms of an infinite geometric progression are $m-1,6, m+4$, where $m$ is an integer. Show that $m$ satisfies the equation $m^{2}+3 m-40=0$. Hence find the possible values of $m$ and the common ratio of the progression.
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