Classical Theorems in Plane Geometry 1

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BERKELEY MATH CIRCLE 1999 2000 Classical Theorems in Plane Geometry 1 Zvezdelina Stankova-Frenkel UC Berkeley and Mills College Note: All objects in this handout are planar - i.e. they lie in the usual plane. We say that several points are collinear if they lie on a line. Similarly, several points are concyclic if they lie on a circle; an inscribed (cyclic) polygon has its vertices lying on a circle. If three distinct points A, B and C are collinear, then the directed ratio AB/CB is the ratio of the lengths of segments AB and CB, taken with a sign + if the segments have the same direction (i.e. B is not between A and C), and with a sign if the segments have opposite directions (i.e. B is between A and C). Several objects (lines, circles, etc.) are concurrent if they all intersect in some point. 1. (Menelaus) Let A 1, B 1 and C 1 be three points on the sides BC, CA and AB of ABC. Prove that they are collinear (cf. Fig. 1) iff AB 1 CB 1 CA 1 BA 1 BC 1 AC 1 = 1. Figure 1 Figure 2a 1 This handout was given at the training sessions of the 6 member team, which represented USA at the International Math Olympiad this summer in Romania. Thus, do not be alarmed if you can t do most or any of the problems here, or if you do not understand some of the terminology. These certainly are not typical high school problems rather, they are hard Olympiad type problems. The intention of this handout is to make you think about some concepts and problems, and come to the Math Circle in September wanting to find out their interpretations and solutions.

2. (a) Prove that the interior angle bisectors of two angles of nonisosceles ABC and the exterior angle bisector of the third angle intersect the opposite sides (or their continuations) of ABC in three collinear points. (cf. Fig. 2a) (b) Prove that the exterior angle bisectors of nonisosceles ABC intersect the continuations of opposite sides of ABC in three collinear points. Figure 2c Figure 3 (c) Prove that the tangents at the vertices of nonequilateral ABC to the circumcircle of ABC intersect the continuations of opposite sides of ABC in three collinear points. (cf. Fig. 2c) 3. (Pascal) If the hexagon ABCDEF is cyclic and its opposite sides, AB and DE, BC and EF, CD and F A, are pairwise not parallel, prove that their three points of intersection, X, Y and Z, are collinear. (cf. Fig. 3) The same statement is true if the circle is replaced by an ellipse, hyperbola or parabola. 2 The statement is also true if some of the vertices of the hexagon coincide then replace the corresponding side of the hexagon by the tangent to the circle at the corresponding vertex. Thus, obtain the following: (a) If A = B, C = D, D = F, deduce to Problem 2c. (b) If E = F, formulate the property of any inscribed pentagon. (c) If A = F and D = E, for the inscribed quadrilateral ABCD we have: the intersection points of AB and the tangent at D, of CD and the tangent at A, and of BC and AD, are collinear. (d) If A = F and C = D, the intersection points of the pairs of opposite sides of an inscribed quadrilateral and the intersection of the tangents at two opposite vertices are collinear. (Actually, the tangents at any pair of opposite vertices should also work.) 2 These all are conics, i.e. projectively equivalent to a circle. 2

4. (Desargues) ABC and A 1 B 1 C 1 are positioned in such a way that lines AA 1, BB 1, and CC 1 intersect in a point O. If lines AB and A 1 B 1, AC and A 1 C 1, BC and B 1 C 1 are pairwise not parallel, prove that their points of intersection, L, M and N, are collinear. (cf. Fig. 4) Figure 4 Figure 5 Note: The incircle of ABC is the circle inscribed in ABC (i.e. tangent to all three sides of the triangle.) Its center is called the incenter of ABC; it lies on the angle bisectors of ABC. The excircle of ABC tangent to side AB is the circle tangent to side AB and to the extentions of sides BC and AC. Its center is called an excenter of ABC. On what bisectors does this excenter lie? Finally, the circumcircle of ABC is the circle passing through the vertices A, B and C. Its center is called the circumcenter of ABC; it lies on the perpendicular bisectors of the sides of the triangle. 5. Prove that the midpoint K of the altitude CH in ABC, the incenter I of ABC, and the tangency point T on AB of the excircle of ABC (tangent to side AB) are collinear. (cf. Fig. 5) 6. (Gauss s line with respect to l) Line l intersects the sides (or continuations of) BC, CA and AB of ABC in points P 1, P 2 and P 3. Prove that the midpoints M 1, M 2 and M 3 of AP 1, BP 2 and CP 3 are collinear. (cf. Fig. 6) Figure 6 Figure 7 3

7. Let ABCD be a quadrilateral with perpendicular diagonals intersecting in P. The feet of the perpendiculars from P to sides AB, BC, CD and DA are P 1, P 2, P 3 and P 4. Prove that lines P 1 P 2, P 3 P 4 and CA are concurrent. (cf. Fig. 7) 8. (Simpson) Prove that the feet of the perpendiculars dropped from a point M on the circumcircle k of ABC to the sides of the triangle are collinear. More generally, let S be the area of ABC, R the circumradius, and d the radius of a circle ɛ concentric to k. Let A 1, B 1 and C 1 be the feet of the perpendiculars dropped from an arbitrary point on ɛ to the sides of ABC. Prove that the area S 1 of A 1 B 1 C 1 is given by the formula S 1 = 1S 4 1 d 2. R In particular, 2 when ɛ = k, then S 1 = 0, and hence A 1, B 1 and C 1 are collinear. (cf. Fig. 8) Figure 8 9. (Salmon) Through a point M on a circle ɛ draw three arbitrary chords MA, MB and MC, and using each chord as a diameter, draw three new circles ɛ 1, ɛ 2, and ɛ 3. Prove that the pairwise intersections of the ɛ i s (other than M) are collinear. Note: Let H be the orthocenter of ABC (i.e. the intersection of the altitudes of the triangle.) The Euler circle of 9 points for ABC is the circle passing through the midpoints of the sides of ABC, the midpoints of AH, BH and CH, and the feet of the altitudes of ABC. In fact, the center of this circle is the midpoint of HO (O is the circumcenter of ABC), and its radius is half of the circumradius of ABC. Why? (cf. Fig. 10a) 10. Prove that Simpson s line of ABC with respect to point M on the circumscribed circle k of ABC, line MH where H is the orthocenter of ABC, and the Euler circle of 9 points for ABC are concurrent. (cf. Fig. 10b) 11. (Ceva) Let A, B and C be three points on the sides (or continuations of) BC, CA, AB of ABC. Prove that AA, BB, CC are concurrent or are parallel iff AB CB CA BA BC AC = 1. 4

Figure 10a Figure 10b 12. (Gergonne s point) Prove that the lines connecting the vertices of a triangle with the points of tangency of the inscribed circle are concurrent. (cf. Fig. 12) Figure 12 Figure 13 13. (Nagel s point) Prove that the lines connecting the vertices of a triangle with the corresponding points of tangency of the three externally inscribed circles are concurrent (cf. Fig. 13.) Note that these are also the three lines through the vertices of the triangle and dividing each its perimeter into two equal parts. 14. Let M be an arbitrary point on side AB of ABC. Let P and Q be the intersection points of the angle bisectors of BMC and AMC with sides BC and AC, respectively. Prove that lines AP, BQ and CM are concurrent. 15. Let A 1, B 1, C 1 be points on the sides of an acuteangled ABC so that the lines AA 1, BB 1 and CC 1 are concurrent. Prove that CC 1 is an altitude in ABC iff it is the angle bisector of B 1 C 1 A 1. 16. In the acuteangled ABC a semicircle k with center O on side AB is inscribed. Let M and N be the points of tangency of k with sides BC and AC. Prove that lines AM, BN and the altitude CD of ABC are concurrent. (cf. Fig. 16) 5

17. A circle k intersects side AB of ABC in C 1 and C 2, side CA in B 1 and B 2, side BC in A 1 and A 2. The order of these points on k is: A 1, A 2, B 1, B 2, C 2, C 1. Prove that lines AA 1, BB 1, CC 1 are concurrent iff AA 2, BB 2, CC 2 are concurrent. (cf. Fig. 17) Figure 16 Figure 17 Figure 18 18. Let the points of tangency of the incircle of ABC with the sides AB, BC and CA be C 1, A 1 and B 1, and let A 2, B 2 and C 2 be their reflections across the incenter I of ABC. Prove that lines AA 2, BB 2 and CC 2 are concurrent. (cf. Fig. 18) 19. (Gauss) If the two pairs of opposite sides of a quadrilateral ABCD intersect in E and F, prove that the midpoint N of EF lies on the line through the midpoints L and M of the diagonals AC and BD. (cf. Fig. 19) Figure 19 Figure 20 20. Point P lies inside ABC. Lines AP, BP, CP intersect the sides BC, CA, AB in A 1, B 1, C 1, respectively, and L, M, N, L 1, M 1, N 1 are the midpoints of the segments BC, CA, AB, B 1 C 1, C 1 A 1, A 1 B 1. Prove that LL 1, MM 1 and NN 1 are concurrent. (cf. Fig. 20) 21. Let P, Q and R be points on the sides BC, CA and AB of ABC. Let O 1, O 2 and O 3 be the circumcenters of AQR, BRP and CP Q. Prove that O 1 O 2 O 3 ABC. (cf. Fig. 21) 6

Figure 21 Figure 22 22. (IMO 81) Three congruent circles pass through point P inside ABC. Each circle is inside ABC and is tangent to two of its sides. Prove that the circumcenter O and incenter I of ABC and P are collinear. (cf. Fig. 22) 23. (Brianchon) If the hexagon ABCDEF is circumscribed around a circle, prove that its three diagonals AD, BE and CF are concurrent. (cf. Fig. 23) Figure 23 Figure 24 24. (Saint Petersburg Olympiad) Point I is the incenter of ABC. Some circle with center I intersects side BC in A 1 and A 2, side CA in B 1 and B 2, and side AB in C 1 and C 2. The six points obtained in this way lie on the circle in the following order: A 1, A 2, B 1, B 2, C 1, C 2. Points A 3, B 3 and C 3 are the midpoints of the arc A 1 A 2, B 1 B 2 and C 1 C 2 respectively. Lines A 2 A 3 and B 1 B 3 intersect in C 4, lines B 2 B 3 and C 1 C 3 in A 4, and lines C 2 C 3 and A 1 A 3 in B 4. Prove that the segments A 3 A 4, B 3 B 4 and C 3 C 4 intersect in one point. (cf. Fig. 24) 7

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