geometry problems from South Korean Winter Camp / Program Practice Tests
with aops links in the names
Winter Camp Test 2016-21
There is circle \omega and A, B on it. Circle \gamma_1 tangent to \omega on T and AB on D. Circle \gamma_2 tangent to \omega on S and AB on E. (like the figure below) Let AB\cap TS=C. Prove that CA=CB iff CD=CE
There are three circles w_1, w_2, w_3. Let w_{i+1} \cap w_{i+2} = A_i, B_i, where A_i lies insides of w_i. Let \gamma be the circle that is inside w_1,w_2,w_3 and tangent to the three said circles at T_1, T_2, T_3. Let T_iA_{i+1}T_{i+2}'s circumcircle and T_iA_{i+2}T_{i+1}'s circumcircle meet at S_i. Prove that the circumcircles of A_iB_iS_i meet at two points. (1 \le i \le 3, indices taken modulo 3) .
If one of A_i,B_i,S_i are collinear - the intersections of the other two circles lie on this line. Prove this as well.
Let there be an acute triangle ABC, such that \angle ABC < \angle ACB. Let the perpendicular from A to BC hit the circumcircle of ABC at D, and let M be the midpoint of AD. The tangent to the circumcircle of ABC at A hits the perpendicular bisector of AD at E, and the circumcircle of MDE hits the circumcircle of ABC at F. Let G be the foot of the perpendicular from A to BD, and N be the midpoint of AG. Prove that B, N, F are collinear.
Let there be an acute triangle ABC with orthocenter H. Let BH, CH hit the circumcircle of \triangle ABC at D, E. Let P be a point on AB, between B and the foot of the perpendicular from C to AB. Let PH \cap AC = Q. Now \triangle AEP's circumcircle hits CH at S, \triangle ADQ's circumcircle hits BH at R, and \triangle AEP's circumcircle hits \triangle ADQ's circumcircle at J (\not=A). Prove that RS is the perpendicular bisector of HJ.
Let \gamma_1, \gamma_2, \gamma_3 be mutually externally tangent circles and \Gamma_1, \Gamma_2, \Gamma_3 also be mutually externally tangent circles. For each 1 \le i \le 3, \gamma_i and \Gamma_{i+1} are externally tangent at A_i, \gamma_i and \Gamma_{i+2} are externally tangent at B_i, and \gamma_i and \Gamma_i do not meet. Show that the six points A_1, A_2, A_3, B_1, B_2, B_3 lie on either a line or a circle.
For a point P on the plane, denote by \lVert P \rVert the distance to its nearest lattice point. Prove that there exists a real number L > 0 satisfying the following condition:
For every \ell > L, there exists an equilateral triangle ABC with side-length \ell and \lVert A \rVert, \lVert B \rVert, \lVert C \rVert < 10^{-2017}.
Let \triangle ABC be a triangle with \angle A \neq 60^\circ. Let I_B, I_C be the B, C-excenters of triangle ABC, let B^\prime be the reflection of B with respect to AC, and let C^\prime be the reflection of C with respect to AB. Let P be the intersection of I_C B^\prime and I_B C^\prime. Denote by P_A, P_B, P_C the reflections of the point P with respect to BC, CA, AB. Show that the three lines A P_A, B P_B, C P_C meet at a single point.
ABC is an obtuse triangle satisfying \angle A>90^\circ, and its circumcenter O and circumcircle \omega_1. Let \omega_2 be a circle passing C with center B. \omega_2 meets BC at D. \omega_1 meets AD and \omega_2 at E and F(\neq C), respectively. AF meets \omega_2 at G(\neq F). Prove that the intersection of CE and BG lies on the circumcircle of AOB.
Denote A_{DE} by the foot of perpendicular line from A to line DE. Given concyclic points A,B,C,D,E,F, show that the three points determined by the lines A_{FD}A_{DE} , B_{DE}B_{EF} , C_{EF}C_{FD}, and the three points determined by the lines D_{CA}D_{AB} , E_{AB}E_{BC} , F_{BC}F_{CA} are concyclic.
Let \Delta ABC be a triangle with circumcenter O and circumcircle w. Let S be the center of the circle which is tangent with AB, AC, and w (in the inside), and let the circle meet w at point K. Let the circle with diameter AS meet w at T. If M is the midpoint of BC, show that K,T,M,O are concyclic.
Let \Delta ABC be a triangle and P be a point in its interior. Prove that \frac{[BPC]}{PA^2}+\frac{[CPA]}{PB^2}+\frac{[APB]}{PC^2} \ge \frac{[ABC]}{R^2} where R is the radius of the circumcircle of \Delta ABC, and [XYZ] is the area of \Delta XYZ.
Find all functions f:\mathbb{R}^+\rightarrow\mathbb{R}^+ such that if a,b,c are the length sides of a triangle, and r is the radius of its incircle, then f(a),f(b),f(c) also form a triangle where its radius of the incircle is f(r).
\omega_1,\omega_2 are orthogonal circles, and their intersections are P,P'. Another circle \omega_3 meets \omega_1 at Q,Q', and \omega_2 at R,R'. (The points Q,R,Q',R' are in clockwise order.) Suppose P'R and PR' meet at S, and let T be the circumcenter of \triangle PQR. Prove that T,Q,S are collinear if and only if O_1,S,O_3 are collinear. (O_i is the center of \omega_i for i=1,2,3.)
\triangle ABC and \triangle A_1B_1C_1 are perspective triangles. (ABB_1) and (ACC_1) meet at A_2 (\neq A). Define B_2,C_2 analogously. Prove that AA_2, BB_2,CC_2 are concurrent.
I is the incenter of a given triangle \triangle ABC. The angle bisectors of ABC meet the sides at D,E,F, and EF meets (ABC) at L and T (F is on segment LE.). Suppose M is the midpoint of BC. Prove that if DT is tangent to the incircle of ABC, then IL bisects \angle MLT.
\square ABCD is a quadrilateral with \angle A=2\angle C <90^\circ. I is the incenter of \triangle BAD, and the line passing I and perpendicular to AI meets rays CB and CD at E,F respectively. Denote O as the circumcenter of \triangle CEF. The line passing E and perpendicular to OE meets ray OF at Q, and the line passing F and perpendicular to OF meets ray OE at P. Prove that the circle with diameter PQ is tangent to the circumcircle of \triangle BCD.
Let ABC be a triangle with \angle A=60^{\circ}. Point D, E in lines \overrightarrow{AB}, \overrightarrow{AC} respectively satisfies DB=BC=CE. (A,B,D lies on this order, and A,C,E likewise) Circle with diameter BC and circle with diameter DE meets at two points X, Y. Prove that \angle XAY\ge 60^{\circ}
E,F are points on AB,AC that satisfies (B,E,F,C) cyclic. D is the intersection of BC and the perpendicular bisecter of EF, and B',C' are the reflections of B,C on AD. X is a point on the circumcircle of \triangle{BEC'} that AB is perpendicular to BX,and Y is a point on the circumcircle of \triangle{CFB'} that AC is perpendicular to CY. Show that DX=DY.
The acute triangle ABC satisfies \overline {AB}<\overline {BC}<\overline {CA}. Let H a orthocenter of ABC, D a intersection point of AH and BC, E a intersection point of BH and AC, and M a midpoint of segment BC.
A circle with center E and radius AE intersects the segment AC at point F(\neq A), and circumcircle of triangle BFC intersects the segment AM at point S. Let P(\neq D), Q(\neq F) a intersection point of circumcircle of triangle ASD and DF, circumcircle of triangle ASF and DF respectively. Also, define R as a intersection point of circumcircles of triangle AHQ and AEP. Prove that R lies on line DF.
The acute triangle ABC satisfies \overline {AB}<\overline {BC}<\overline {CA}. Denote the foot of perpendicular from A,B,C to opposing sides as D,E,F. Let P a foot of perpendicular from F to DE, and Q(\neq F) a intersection point of line FP and circumcircle of BDF. Prove that \angle PBQ=\angle PAD.
Older Winter Camp Tests
Given an acute triangle ABC with AB \neq AC, let the excircle for A meets lines AB,AC,BC at P,Q,R. Let BC and PQ meet at X, and the circumcircles of XCQ and BCP meet at Y \neq C. Prove that \frac {RP}{PX} = \frac {RY}{YX}.
Korea Winter (probably 2019)
ABCD is a quadrilateral with \angle A=2\angle C <90^\circ. I is the incenter of \triangle BAD, and the line passing I and perpendicular to AI meets rays CB and CD at E,F respectively. Denote O as the circumcenter of \triangle CEF. The line passing E and perpendicular to OE meets ray OF at Q, and the line passing F and perpendicular to OF meets ray OE at P. Prove that the circle with diameter PQ is tangent to the circumcircle of \triangle BCD.
Korea Winter (probably 2019)
There is a triangle ABC with incenter I. Let BI \cap AC=E, CI \cap AB=F. EF meets (ABC) with P,Q. And excircle of A meets ABC with M,N. Four points are in the circle in P,Q,M,N clockwise. Prove that PQ=2PM=2QN.
Summer Camp Test 2016
Let the incircle of triangle ABC meet the sides BC, CA, AB at D, E, F, and let the A-excircle meet the lines BC, CA, AB at P, Q, R. Let the line passing through A and perpendicular to BC meet the lines EF, QR at K, L. Let the intersection of LD and EF be S, and the intersection of KP and QR be T. Prove that A, S, T are collinear.
There are distinct points A_1, A_2, \dots, A_{2n} with no three collinear. Prove that one can relabel the points with the labels B_1, \dots, B_{2n} so that for each 1 \le i < j \le n the segments B_{2i-1} B_{2i} and B_{2j-1} B_{2j} do not intersect and the following inequality holds.
B_1 B_2 + B_3 B_4 + \dots + B_{2n-1} B_{2n} \ge \frac{2}{\pi} (A_1 A_2 + A_3 A_4 + \dots + A_{2n-1} A_{2n})
Other Summer Camp Tests
ABC is a given triangle, and P is a point on segment BC. Define I,J as the incenters of ABP and ACP. Prove that (PIJ) pass a fixed point.
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