Difference between revisions of "2011 AIME II Problems/Problem 6"
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Thus the answer is <math>\frac{\binom{10}{4}-50}{2} = \boxed{080}.</math> | Thus the answer is <math>\frac{\binom{10}{4}-50}{2} = \boxed{080}.</math> | ||
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+ | ==Solution 5== | ||
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+ | Think about a,b,c,and d as distinct objects, that we must place in 4 of 10 spaces. However, in only 1 of 24 of these combinations, will the placement of these objects satisfy the condition in the problem. So we know the total number of ordered quadruples is <math>(10*9*8*7/24)=210</math> | ||
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+ | Next, intuitively, the number of quadruples where <math>a+d>b+c</math> is equal to the number of quadruples where <math>a+d<b+c</math>. So we need to find the number of quadruples where the two quantities are equal. To do this, all we have to do is consider the cases when <math>a-d</math> ranges from 3 to 9. It would seem natural that a range of 3 would produce 1 option, and a range of 4 would produce 2 options. However, since b and c cannot be equal, a range of 3 or 4 produces 1 option each, a range of 5 or 6 produces 2 options each, a range of 7 or 8 produces 3 options each, and a range of 9 will produce 4 options. In addition, a range of n has 10-n options for combinations of a and d. Multiplying the number of combinations of a and d by the corresponding number of options for b and c gives us 50 total quadruplets where <math>a+d=b+c</math>. | ||
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+ | So the answer will be <math>\frac{210-50}{2} = \boxed{080}.</math> | ||
==See also== | ==See also== |
Revision as of 02:01, 13 December 2019
Contents
Problem 6
Define an ordered quadruple of integers as interesting if , and . How many interesting ordered quadruples are there?
Solution 1
Rearranging the inequality we get . Let , then is a partition of 11 into 5 positive integers or equivalently: is a partition of 6 into 5 non-negative integer parts. Via a standard stars and bars argument, the number of ways to partition 6 into 5 non-negative parts is . The interesting quadruples correspond to partitions where the second number is less than the fourth. By symmetry, there are as many partitions where the fourth is less than the second. So, if is the number of partitions where the second element is equal to the fourth, our answer is .
We find as a sum of 4 cases:
- two parts equal to zero, ways,
- two parts equal to one, ways,
- two parts equal to two, ways,
- two parts equal to three, way.
Therefore, and our answer is
Solution 2
Let us consider our quadruple (a,b,c,d) as the following image xaxbcxxdxx. The location of the letter a,b,c,d represents its value and x is a place holder. Clearly the quadruple is interesting if there are more place holders between c and d than there are between a and b. 0 holders between a and b means we consider a and b as one unit ab and c as cx yielding ways, 1 holder between a and b means we consider a and b as one unit axb and c as cxx yielding ways, 2 holders between a and b means we consider a and b as one unit axxb and c as cxxx yielding ways and there cannot be 3 holders between a and b so our total is 56+20+4=.
Solution 3 (Slightly bashy)
We first start out when the value of .
Doing casework, we discover that . We quickly find a pattern.
Now, doing this for the rest of the values of and , we see that the answer is simply:
Solution 4 (quick)
Notice that if , then , so there is a 1-to-1 correspondence between the number of ordered quadruples with and the number of ordered quadruples with .
Quick counting gives that the number of ordered quadruples with is 50.
Thus the answer is
Solution 5
Think about a,b,c,and d as distinct objects, that we must place in 4 of 10 spaces. However, in only 1 of 24 of these combinations, will the placement of these objects satisfy the condition in the problem. So we know the total number of ordered quadruples is
Next, intuitively, the number of quadruples where is equal to the number of quadruples where . So we need to find the number of quadruples where the two quantities are equal. To do this, all we have to do is consider the cases when ranges from 3 to 9. It would seem natural that a range of 3 would produce 1 option, and a range of 4 would produce 2 options. However, since b and c cannot be equal, a range of 3 or 4 produces 1 option each, a range of 5 or 6 produces 2 options each, a range of 7 or 8 produces 3 options each, and a range of 9 will produce 4 options. In addition, a range of n has 10-n options for combinations of a and d. Multiplying the number of combinations of a and d by the corresponding number of options for b and c gives us 50 total quadruplets where .
So the answer will be
See also
2011 AIME II (Problems • Answer Key • Resources) | ||
Preceded by Problem 5 |
Followed by Problem 7 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.