Belarus Team Selection Test 2010

rsoldo · 07.08.2024, 14:24

Points $H$ and $T$ are marked respectively on the sides $BC$ abd $AC$ of triangle $ABC$ so that $AH$ is the altitude and $BT$ is the bisectrix $ABC$ . It is known that the gravity center of $ABC$ lies on the line $HT$ .
a) Find $AC$ if $BC$ =a and $AB$ =c.
b) Determine all possible values of $\frac{c}{a}$ for all triangles $ABC$ satisfying the given condition.

drzewo · 07.08.2024, 15:03

the key point of the problem is that the gravity center of a triangle is situated in the intersection of the medians, I guess

-- 07.08.2024, 16:14 --

introduce a rectangular coordinate frame $Hxy$ such that $BC\subset Hx$
and let $A=(0,\alpha),\quad B=(-\beta,0),\quad C=(\sigma,0)$

provincialka · 09.08.2024, 00:09

Может, применить несколько раз теорему Менелая? К разным треугольникам.

Впрочем, это будет громоздко, наверное, не лучше, чем координатный метод...

rsoldo · 29.08.2024, 13:54

a) ( the drawing is missing )
From $m_a=\sqrt{\frac{2b^2+2c^2-a^2}{4}}$ , and the cosine rule from triangle $ABM$ we have:
$c^2=\frac{2b^2+2c^2-a^2}{4}+\frac{a^2}{4}-2\cdot\frac{a}{2}\cdot \sqrt{\frac{2b^2+2c^2-a^2}{4}}\cdot \cos \angle BMD$
$\cos\angle BMD=\frac{b^2-c^2}{a\cdot \sqrt{2b^2+2c^2-a^2}},$ and because $\cos\angle BMD=\frac{HM}{m_a}$ we have
$HM=\frac{b^2-c^2}{2a} \implies HC = \frac{{b^2} - {c^2}}{2a} + \frac{a}{2} = \frac{{b^2} + {a^2} - {c^2}}{2a}.$
From Menelaus theorem in $AMC$ with transversal $MGA$ we get: $\frac{{HM}}{{HC}} \cdot \frac{{CT}}{{TA}} \cdot \frac{{AG}}{{GM}} = 1 \Leftrightarrow$

$\frac{{{b^2} - {c^2}}}{{{b^2} + {a^2} - {c^2}}} \cdot \frac{a}{c} \cdot 2 = 1 \Leftrightarrow$ $\boxed{b = \sqrt {\frac{{c(2ac + {a^2} - {c^2})}}{{2a - c}}} }.$

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Belarus Team Selection Test 2010