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I was reading a text book and came across the following interesting short-cut:

If two items are sold, each at $X$, one at a gain of $P\%$ and the other at a loss of $P\%$, then overall loss percentage $= P^2/100 \%$.

Can anyone please explain the underlying logic on the basis of which this shortcut works?

Thanks in advance!

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    "..... something goes up x%, then down x%, ......The math is perfect, but the interpretations put on it are sometimes amazing." One interpretation I that I always enjoy is that the **average gain** is $\frac{x\% + (-x\%)}{2} = 0\%$ and so the customer has broken even.2011-12-24

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A gain of P% that results in an item cost of $X$ means that the original price, $C_1$, was such that $\left(1 + \frac{P}{100}\right)C_1 = X.$ A loss of P% that results in an item cost of $X$ means that the original price, $C_2$, was such that $\left(1 - \frac{P}{100}\right)C_2 = X.$ In other words, your costs were $C_1 + C_2 = \frac {X}{1 + \frac{P}{100}} + \frac{X}{1-\frac{P}{100}} = \frac{100X}{100+P} + \frac{100x}{100-P}.$ On the other hand, you received $X+X = 2X$. So what is the total profit/loss? It's equal to the amount received minus the amount spent: $\begin{align*} \text{Profit} &= \text{Revenue} - \text{Cost}\\ &= 2X - \frac{100X}{100+P} + \frac{100X}{100-P} \\ &= 2X- \frac{100X(100-P)+100X(100+P)}{(100+P)(100-P)} \\ &= 2X - 100X\left(\frac{100-P+100+P}{(100+P)(100-P)}\right)\\ &= 2x - 100X\left(\frac{200}{(100+P)(100-P)}\right)\\ &= 2x\left( 1 - \frac{10000}{(100+P)(100-P)}\right)\\ &= 2X\left(1 - \frac{10000}{10000 - P^2}\right)\\ &= 2X\left(\frac{10000-P^2 - 10000}{1000-P^2}\right)\\ &= 2X\left(-\frac{P^2}{10000}\right)\\ &= 2X\left( - \frac{(P^2/100)}{100}\right). \end{align*}$ So your total loss is $(P^2/100)$%.

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Given that

  1. Item 1 was bought at a cost I call $C_{1}$, sold at $X$ with a relative gain $p=\frac{X-C_{1}}{C_{1} }>0$, with $p=\frac{P}{100}$, where $P$ is in percentage.

  2. Item 2 was bought at a cost I call $C_{2}$, sold at $X$ with a relative loss $p=\frac{C_{2}-X}{C_{2}}>0$.

  3. And items 1+2 were sold at $2X$,

then the overall relative loss $q>0$ is given by $q=\frac{C_{1}+C_{2}-2X}{C_{1}+C_{2}}.$

From 1 and 2 we get respectivelly

$C_{1} =\frac{X}{p+1},\qquad C_{2} =-\frac{X}{p-1}.$

So $q$ can be rewritten as

$q =\dfrac{\dfrac{X}{p+1}-\dfrac{X}{p-1}-2X}{\dfrac{X}{p+1}-\dfrac{X}{p-1}}=\dfrac{\dfrac{1}{p+1}-\dfrac{1}{p-1}-2}{\dfrac{1}{p+1}-\dfrac{1}{p-1}}=\dfrac{-2p^{2}}{-2}=p^{2}=\left( \dfrac{P}{100}\right) ^{2}.$

The overall loss in percentage is

$100q=\frac{P^{2}}{100},$

which proves the assertion.

Numerical example:

  • Item 1: $C_{1}=100$, sold at $X=108$. The relative gain is $p=\frac{108-100}{% 100}=\frac{8}{100}=0.08$, $P=8.$
  • Item 2: $C_{2}=\frac{108}{0.92}\approx 117.39$, sold at $X=108$. The relative loss is $\frac{108/0.92-108}{108/0.92}=0.08=p$.
  • Item 1 + Item 2: $C_{1}+C_{2}=100+108/0.92\approx 217.39.$

The overall loss is

$q=\frac{100+108/0.92-2\cdot 108}{100+108/0.92}=0.0064=0.08^{2}=\left( \frac{8}{100}\right) ^{2},$

and $100q=100\left( \frac{8}{100}\right) ^{2}=0.64.$

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To work it out, the original costs of the items $C_1$ and $C_2$ are such that $\dfrac{X-C_1}{C_1}= \dfrac{P}{100}$ and $\dfrac{X-C_2}{C_2}= -\dfrac{P}{100}$ so $C_1=\dfrac{100X}{100+P}$ and $C_2=\dfrac{100X}{100-P}$. Add the two costs together and you get $C_1+C_2=\dfrac{20000X}{10000-P^2}$

The overall profit percentage (it is a loss since it is negative) is

$ 100 \left(\dfrac{2X-(C_1+C_2)}{C_1+C_2}\right) = 100 \left(\dfrac{2X-\frac{20000X}{10000-P^2}}{\frac{20000X}{10000-P^2}}\right) = \dfrac{-P^2}{100} $