I did Arithmetic Progression and Geometric Progression two years ago but this is challenging to me. If 27 is the Pth term,8 is the Qth term and 12 is the Sth term of a G.P,then show that 3S=2Q+P
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You need to state that they are the Pth term of which sequence. Is it an arithmetic progression, geometric progression, natural numbers?? – Calvin Lin Jul 09 '13 at 00:49
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Geometric Progression – Dr. NGILAZI BANDA Jul 09 '13 at 01:00
1 Answers
As usual, let $a$ be the first term of the geometric progression, and let $r$ be the common ratio.
So we know that
$$ar^{P-1}=27, \qquad ar^{Q-1}=8, \qquad ar^{S-1}=12.$$
Now note that $12^3=(8^2)(27)$.
It follows that $$(ar^{S-1})^3 =(ar^{Q-1})^2(ar^{P-1}).\tag{1}$$ Expand, and the result falls out. On the left, we have $a^3r^{3S-3}$ and on the right we have $a^3 r^{2Q+P-3}$. Cancel the $a^3$. We get that $r^{3S-3}=r^{2Q+P-3}$ and therefore $3S-3=2Q+P-3$.
Remark: We cheated a little. The equality $12^3=(8^2)(27)$ looks as if it was pulled out of a hat, but it really wasn't. By looking at (1), one can see that the desired result is equivalent to the assertion that the cube of $Ar^{S-1}$ is equal to the square of $ar^{Q-1}$ times $ar^{P-1}$. But the condition $(12)^3=(8^2)(27)$ is easy to verify by multiplying, or, better, factoring.
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