Difference between revisions of "2017 AIME I Problems/Problem 10"

(Solution 2)
(Solution 2)
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In order for the product to be a real number, since both denominators are real numbers, we must have the numerator of <math>\frac {z-z_2}{z-z_3}</math> be a multiple of the conjugate of <math>15i-4</math>, namely <math>-15i-4</math> So, we have <math>(a-18)(a-78)+(b-39)(b-99) = -4k</math> and <math>(a-78)(b-39)-(a-18)(b-99) = -15k</math> for some real number <math>k</math>.
 
In order for the product to be a real number, since both denominators are real numbers, we must have the numerator of <math>\frac {z-z_2}{z-z_3}</math> be a multiple of the conjugate of <math>15i-4</math>, namely <math>-15i-4</math> So, we have <math>(a-18)(a-78)+(b-39)(b-99) = -4k</math> and <math>(a-78)(b-39)-(a-18)(b-99) = -15k</math> for some real number <math>k</math>.
  
Then, we get:<math>(a-18)(a-78)+(b-39)(b-99) = \frac{4}{15}(a-78)(b-39)-(a-18)(b-99)</math>
+
Then, we get:<math>(a-18)(a-78)+(b-39)(b-99) = \frac{4}{15}[(a-78)(b-39)-(a-18)(b-99)]</math>
  
 
Expanding both sides and combining like terms, we get:
 
Expanding both sides and combining like terms, we get:

Revision as of 18:27, 9 March 2017

Problem 10

Let $z_1=18+83i,~z_2=18+39i,$ and $z_3=78+99i,$ where $i=\sqrt{-1}.$ Let $z$ be the unique complex number with the properties that $\frac{z_3-z_1}{z_2-z_1}~\cdot~\frac{z-z_2}{z-z_3}$ is a real number and the imaginary part of $z$ is the greatest possible. Find the real part of $z$.

Solution

(This solution's quality may be very poor. If one feels that the solution is inadequate, one may choose to improve it.)

Let us write $\frac{z_3 - z_1}{z_2 - z_1}$ be some imaginary number with form $r_1 (\cos \theta_1 + i \sin \theta_1).$ Similarly, we can write $\frac{z-z_2}{z-z_3}$ as some $r_2 (\cos \theta_2 + i \sin \theta_2).$

The product must be real, so we have that $r_1 r_2 (\cos \theta_1 + i \sin \theta_1) (\cos \theta_2 + i \sin \theta_2)$ is real. Of this, $r_1 r_2$ must be real, so the imaginary parts only arise from the second part of the product. Thus we have

\[(\cos \theta_1 + i \sin \theta_1) (\cos \theta_2 + i \sin \theta_2) = \cos \theta_1 \cos \theta_2 - \sin \theta_1 \sin \theta_2 + i(\cos \theta_1 \sin \theta_2 + \cos \theta_2 \sin \theta_1)\]

is real. The imaginary part of this is $(\cos \theta_1 \sin \theta_2 + \cos \theta_2 \sin \theta_1),$ which we recognize as $\sin(\theta_1 + \theta_2).$ This is only $0$ when $\theta_1 + \theta_2$ is some multiple of $\pi.$ In this problem, this implies $z_1, z_2, z_3$ and $z$ must form a cyclic quadrilateral, so the possibilities of $z$ lie on the circumcircle of $z_1, z_2$ and $z_3.$

To maximize the imaginary part of $z,$ it must lie at the top of the circumcircle, which means the real part of $z$ is the same as the real part of the circumcenter. The center of the circumcircle can be found in various ways, (such as computing the intersection of the perpendicular bisectors of the sides) and when computed gives us that the real part of the circumcenter is $56,$ so the real part of $z$ is $56,$ and thus our answer is $\boxed{056}.$

Solution 2

Algebra Bash

First we calculate $\frac{z_3 - z_1}{z_3 - z_2}$ , which becomes $\frac{15i-4}{11}$.

Next, we define $z$ to be $a-bi$ for some real numbers $a$ and $b$. Then, $\frac {z-z_2}{z-z_3}$ can be written as $\frac{(a-18)+(b-39)i}{(a-78)+(b-99)i}.$ Multiplying both the numerator and denominator by the conjugate of the denominator, we get:

$\frac {[(a-18)(a-78)+(b-39)(b-99)]+[(a-78)(b-39)-(a-18)(b-99)]i}{(a-78)^2+(b-99)^2}$

In order for the product to be a real number, since both denominators are real numbers, we must have the numerator of $\frac {z-z_2}{z-z_3}$ be a multiple of the conjugate of $15i-4$, namely $-15i-4$ So, we have $(a-18)(a-78)+(b-39)(b-99) = -4k$ and $(a-78)(b-39)-(a-18)(b-99) = -15k$ for some real number $k$.

Then, we get:$(a-18)(a-78)+(b-39)(b-99) = \frac{4}{15}[(a-78)(b-39)-(a-18)(b-99)]$

Expanding both sides and combining like terms, we get:

$a^2 - 112a +b^2 - 112b + \frac{1989}{5} = 0$

which can be rewritten as:

$(a-56)^2 + (b-56)^2 = \frac{29371}{5}$

Now, common sense tells us that to maximize $b$, we would need to maximize $(b-56)^2$. Therefore, we must set $(a-56)^2$ to its lowest value, namely 0. Therefore, $a$ must be $\boxed{056}.$

~stronto

See Also

2017 AIME I (ProblemsAnswer KeyResources)
Preceded by
Problem 9
Followed by
Problem 11
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

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