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first of all I am sorry if the level of this question is nowhere near the usual level of questions on this site because my math knowledge is still very basic. I hope you won't mind.

I found this problem on some site:

"A basket of oranges costs 20 dollars, a basket of pears costs 30 dollars and a basket of kiwi fruits costs 40 dollars. Eight baskets of these fruits were bought for 230 dollars. What is the largest possible number of baskets of kiwi fruits that were bought?"

The answer on the site is explained by just putting values in and see if they work. However I would like to know if there is a mathematical method of solving this.

So let me make a system of equations:

$20o+30p+40k=230$

$o+p+k=8$

extra restrictions:

$o, p, k$ are natural numbers

$k$ has to be as large as possible.

Is something like this solvable mathematically without putting in values and see if they work? If yes, how?

3 Answers 3

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It is, but these are more complicated. If we bought $O$ orange baskets, $P$ pear baskets, and $K$ kiwi baskets, we have that

$20O+30P+40K=230$ $O+P+K=8$

So now we combine the equations:

$20(O+P+K)+10P+20K=230$ $160+10P+20K=230$ $10P+20K=70$ $P+2K=7$

now the $2K$ number is clearly even. But the right side is $odd$, meaning that we must have bought an odd number of pear baskets. So we know that $0\leq P \leq 8$, and that $P$ is odd. So our options for $P$ are in $1,3,5,7$. Looking at $P+2K=7$, we see that $K$ can be at most $3$ (if $P=1$).

More generally, $K$ can be $3,2,1,0$. So we have four different options:

$O=4, P=1, K=3$ $O=3, P=3, K=2$ $O=2, P=5, K=1$ $O=1, P=7, K=0$

  • 0
    Well the integers are closed under addition and subtraction, so if $P$ and $K$ are integers, then $O=8-P-K$ must be as well. All that we need to show is that $O$ is non-negative. If $P+2K=7$, then $P+K\leq7$. Since $O+P+K=8$, this implies that $O$ can't be lower than $1$.2012-09-13
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Since $20o+30p+40a=230$, we have $2o+3p+4a=23$ and from the second equation $o=8-p-a$ (Hence $p+a\leq8$). Substituting into the first equation, you get $16-2p-2a+3p+4a=23$, i.e. $p+2a=7$. So $p=7-2a$. This implies that $2a\leq7$, and since we deal with natural numbers, we have $a\leq3$. It's left to check that it is possible to have $a=3$: then $b=7-6=1$ and $o=8-3-1=4$. So we have that the maximal value of $a$ is $3$.

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Starting with your equations $20o+30p+40k=230$ $o+p+k=8$ it is clear (if the solutions are all to be positive) that $k$ can be at most $5$, otherwise $40k\geq 240$. Now, work through the values one-by-one - try $k=5$, then $k=4$, and so on. For each of these substitutions, you can try solving the two resulting equations for $o$ and $p$.

But $k=5$ and $k=4$ don't lead to solutions with positive integers for $o$ and $p$, so these cases can be rejected. You'll find the correct solution when you get to $k=3$.