2018 AIME II Exam Solutions
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All of the real AMC 8, AMC 10, AMC 12, and AIME problems in our complete solution collection are used with official legal permission of the Mathematical Association of America (MAA).
1.
Points and lie in that order along a straight path where the distance from to is meters. Ina runs twice as fast as Eve, and Paul runs twice as fast as Ina. The three runners start running at the same time with Ina starting at and running toward Paul starting at and running toward and Eve starting at and running toward When Paul meets Eve, he turns around and runs toward Paul and Ina both arrive at at the same time. Find the number of meters from to
Difficulty rating: 1950
Solution:
Let so and let Eve's speed be so Ina runs at and Paul at Paul and Eve start at and running toward each other, so together they cover the meters between them, with Paul covering of it. Paul then retraces that distance back to so when he reaches he has run meters in total.
Ina reaches at the same moment, having run meters. Since Paul runs twice as fast as Ina, he has run meters in that time. Therefore which gives so
2.
Let and and for define recursively to be the remainder when is divided by Find
Difficulty rating: 1970
Solution:
Computing successive terms gives Since and each term depends only on the previous three, the sequence is periodic with period
Therefore and so the product is
3.
Find the sum of all positive integers such that the base- integer is a perfect square and the base- integer is a perfect cube.
Difficulty rating: 2170
Solution:
The conditions say is a perfect square and is a perfect cube. Since is odd and forces the cube must be one of giving
The corresponding values of for the positive candidates are and only (for ) and (for ) are perfect squares. The requested sum is
4.
In equiangular octagon and The self-intersecting octagon encloses six non-overlapping triangular regions. Let be the area enclosed by that is, the total area of the six triangular regions. Then where and are relatively prime positive integers. Find
Difficulty rating: 2640
Solution:
Since the interior angles are all and the sides are diagonals of unit squares, the octagon fits on a lattice: The path is carried to itself by the rotation about Let and be the points where and cross and let Segment has slope so and by symmetry and
The six enclosed regions are the four congruent corner triangles like and the two small congruent triangles like Triangle has base and height so its area is Triangle has base and height so its area is Therefore and
5.
Suppose that and are complex numbers such that and where Then there are real numbers and such that Find
Difficulty rating: 2450
Solution:
Multiplying the three equations gives Since we get
Dividing by each given product yields with matching signs. Hence so and
6.
A real number is chosen randomly and uniformly from the interval The probability that the roots of the polynomial are all real can be written in the form where and are relatively prime positive integers. Find
Difficulty rating: 2510
Solution:
Group the terms by whether they involve so the polynomial factors as
All four roots are real exactly when the quadratic factor has real roots, i.e. when which means or The excluded interval has length inside which has length so the probability is The requested sum is
7.
Triangle has side lengths and Points are on segment with between and for and points are on segment with between and for Furthermore, each segment is parallel to The segments cut the triangle into regions, consisting of trapezoids and triangle. Each of the regions has the same area. Find the number of segments that have rational length.
Difficulty rating: 2650
Solution:
Since the regions have equal areas, triangle (the union of the first regions) has area of triangle Each triangle is similar to and lengths scale as the square root of areas, so
This is rational exactly when is a perfect square, which happens exactly when for a positive integer The condition gives so There are such segments.
8.
A frog is positioned at the origin in the coordinate plane. From the point the frog can jump to any of the points or Find the number of distinct sequences of jumps in which the frog begins at and ends at
Difficulty rating: 2920
Solution:
The horizontal jumps are steps of or summing to so as a multiset they are or and the same holds for the vertical jumps. For any choice of the two multisets, every ordering of all the jumps is a valid sequence, and the number of orderings is the multinomial coefficient of the combined multiset.
The nine cases give
The total is
9.
Octagon with side lengths and is formed by removing four -- triangles from the corners of a rectangle with side on a short side of the rectangle, as shown. Let be the midpoint of and partition the octagon into triangles by drawing segments and Find the area of the convex polygon whose vertices are the centroids of these triangles.
Difficulty rating: 2920
Solution:
Each of the triangles has as a vertex, and the centroid of a triangle lies on the segment from to the midpoint of two-thirds of the way out. So the centroid heptagon is the image of the heptagon formed by the midpoints of under a dilation centered at with ratio and its area is
Place the rectangle with so The midpoints are The vertical segments at and have lengths and cutting into two trapezoids of height and a triangle of height
The requested area is
10.
Find the number of functions from to that satisfy for all in
Difficulty rating: 3060
Solution:
Applying to repeatedly shows the condition means that is a fixed point of for every So the elements organize into levels: a nonempty set of fixed points, then elements whose image is a fixed point (but which are not fixed), and the remaining elements, each of which must map to one of the middle elements.
For given and there are choices of fixed points, choices of the middle level, maps from the middle level to the fixed points, and maps for the rest. Summing over the valid pairs (all plus the identity case ) gives
11.
Find the number of permutations of such that for each with at least one of the first terms of the permutation is greater than
Difficulty rating: 3060
Solution:
The condition fails exactly when the first terms are a permutation of for some For a permutation of let be the smallest length for which the prefix is (the full length always works), and let be the number of permutations whose smallest such is We want
Every permutation of decomposes uniquely as a minimal prefix of length ( choices) followed by any arrangement of the remaining values, so Starting from this gives and
12.
Let be a convex quadrilateral with and Assume that the diagonals of intersect at point and that the sum of the areas of triangles and equals the sum of the areas of triangles and Find the area of quadrilateral
Difficulty rating: 3160
Solution:
Let and let Since the equal-area condition simplifies to By symmetry assume
The law of cosines in triangles and (whose angles at are supplementary) gives and so and Similarly triangles and give and Dividing, while subtracting gives hence and so
The total area is
13.
Misha rolls a standard, fair six-sided die until she rolls -- in that order on three consecutive rolls. The probability that she will roll the die an odd number of times is where and are relatively prime positive integers. Find
Difficulty rating: 3270
Solution:
Let be the probability that the total number of rolls is odd; let be that probability given that the first roll is a and given that the first two rolls are - (in each case counting all rolls). Condition on the next roll, noting that whenever the count restarts, the rolls already used flip the required parity. Starting fresh: a leads to state anything else uses one roll, after which an even continuation is needed. After a another means the first roll is wasted, needing an even continuation of the -type; a leads to anything else wastes both rolls. After - a finishes in rolls (odd); a restarts at the -state with two wasted rolls; anything else wastes all three. Thus
The first equation gives substituting the third into the second yields so giving and Since is prime,
14.
The incircle of triangle is tangent to at Let be the other intersection of with Points and lie on and respectively, so that is tangent to at Assume that and where and are relatively prime positive integers. Find
Difficulty rating: 3500
Solution:
Let touch at and at and set and The tangent-chord angle between and chord equals the one between and so and vertical angles give In triangle the law of sines gives and by equal tangents so In triangle since similarly and gives
Adding the two relations, so with and we get hence The identical argument on side (using in triangles and ) gives and by equal tangents from Therefore so and
15.
Find the number of functions from to the integers such that and for all and in
Difficulty rating: 3370
Solution:
Let so each and If of the differences were negative, the sum would be at most so If no difference is negative, the solutions of (with counting s, s, s) are and all such orderings satisfy every pair condition, giving
If then with forces and the remaining four differences are positive and sum to giving functions, and the case is symmetric: in all. Finally, if for some the pair conditions and force and The other three differences are positive and sum to achievable as two s and a or a and two s, each in orders: ways for each of the positions, or functions.
The total is