2020 AMC 12B Problems/Problem 7
Contents
Problem
Two nonhorizontal, non vertical lines in the -coordinate plane intersect to form a angle. One line has slope equal to times the slope of the other line. What is the greatest possible value of the product of the slopes of the two lines?
Solution
Let one of the lines have equation . Let be the angle that line makes with the x-axis, so . The other line will have a slope of . Since the slope of one line is times the other, and is the smaller slope, . If , the other line will have slope . If , the other line will have slope . The first case gives the bigger product of , so our answer is .
~JHawk0224
Solution 2 (bash)
Place on coordinate plane. Lines are The intersection point at the origin. Goes through So by law of sines, lettin we want Simplifying gives so so max and
Law of sines on the green triangle with the red angle (45 deg) and blue angle, where sine blue angle is from right triangle w vertices
~ccx09
Solution 3 (complex)
Let the intersection point is the origin. Let be a point on the line of lesser slope. The mutliplication of by cis 45. and therefore lies on the line of greater slope.
Then, the rotation of by 45 degrees gives a line of slope .
We get the equation and this gives our answer.
~jeffisepic
Solution 4 (matrix transformation)
Multiply by the rotation transformation matrix where
Solution 5 (Cheating)
Let the smaller slope be , then the larger slope is . Since we want the greatest product we begin checking each answer choice, starting with (E).
.
.
This gives and . Checking with a protractor we see that this does not form a 45 degree angle.
Using this same method for the other answer choices, we eventually find that the answer is since our slopes are and which forms a perfect 45 degree angle.
Video Solution
Two solutions https://youtu.be/6ujfjGLzVoE
~IceMatrix
See Also
2020 AMC 12B (Problems • Answer Key • Resources) | |
Preceded by Problem 6 |
Followed by Problem 8 |
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All AMC 12 Problems and Solutions |
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