A Nice Theorem on Mixtilinear Incircles



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A Nice Theorem on Mixtilinear Incircles Khakimboy Egamberganov Abstract There are three mixtilinear incircles and three mixtilinear excircles in an arbitrary triangle. In this paper, we will present many properties of mixtilinear incircles along with a famous theorem involving concyclic points and its proof. A mixtilinear circle of a triangle is a circle tangent to two sides and the circumcircle of the triangle. If this circle is tangent to the circumcircle internally, it is called a mixtilinear incircle of the triangle. Otherwise, it is called a mixtilinear excircle of the triangle. THEOREM. Given a triangle ABC, let ω, Ω, Ω A, be the incircle, circumcircle, and mixtilinear incircle opposite point A, respectively. Let Ω A be tangent to Ω at T A. Suppose that P is a point on Ω such that the tangents from P to ω intersect BC at points X, Y. Then P, T A, X, Y are concyclic. Before the proof of the theorem, we need some theorems and properties about mixtilinear incircles from [1], [], [3]. We will present them with proofs. Suppose that ω, Ω, Ω A, are the incircle, circumcircle, and mixtilinear incircle opposite A of a triangle ABC and T A is the mixtilinear point opposite A. Let I, O be the incenter and the circumcenter of the triangle ABC respectively, and let AI intersect Ω at points A and A 1. Let A be the diametrically opposite point to A 1 on Ω. Analogously, define T B, T C, Ω B, Ω C and B 1, B, C 1, C. Theorem 1. Let Ω A be tangent to the sides AB, AC at points M, N, respectively. Then (i) M, I, N are collinear; (ii) A, I, T A are collinear; Proof. There is a homothety centered at T A that sends Ω to Ω A. (See Picture 1 ). So B 1, N, T A and C 1, M, T A are collinear and MN B 1 C 1. Since AM, AN are tangent lines to Ω A from A, we get that T A A is the symmedian of triangle MT A N. We have C 1 T A A = ACB = B 1 T A A and B 1 T A A = ABC = C 1 T A A. This shows that the line T A A is the isogonal conjugate of the line T A A with respect to MT A N. Hence T A A is the median line of triangle MT A N. Let I be the midpoint of MN. Then BT A I = CT A I = 90 BAC and the quadrilaterals BT A I M and CT A I N are cyclic. So = AMN = ANM MBI = MT A I = C 1 T A A = ABC, NCI = NT A I = B 1 T A A = ACB 1

and I I. Hence M, I, N are collinear. Since T A, I, A are collinear, we get that the points T A, I, A are also collinear. This proves Theorem 1. Theorem. Suppose that M, N are defined in the same way as the previous problem (tangency points of Ω A to AB, AC). Then the lines MN, BC and T A A 1 are concurrent. Proof. We have three circles (BIC), (T A IA 1 ) and Ω. From Theorem 1 we get I is midpoint of MN, IA 1 MN and IT A T A A 1. We can see that the circumcenter of (BIC) is the point A 1 and the circumcenter of (T A IA 1 ) id the midpoint of IA 1. So, the circles (BIC) and (T A IA 1 ) are tangents each to other at point I. Thus, MN is the radical axis of the circles (BIC) and (T A IA 1 ). Moreover, BC is the radical axis of the circles (BIC), Ω and T A A 1 is the radical axis of the circles Ω, (T A IA 1 ). Hence the lines MN, BC and T A A 1 are concurrent at point U (See Picture 1 ). This proves Theorem. Proof of THEOREM. Consider an inversion with center I and radius r (the radius of the incircle of triangle ABC). Suppose that T A inverts to the point K. Also, let D, E, F be the tangency points of the incircle with sides BC, CA, AB respectively. We easily get that B 1 C 1 EF and AI EF, so EF MN. Moreover from Theorem 1 and Theorem, we get that the lines MN, BC, T A A 1 are concurrent at a point U, that IT A U = IDU = 90 and that U, I, D, T A are concyclic (See Picture ). Now let H be the orthocenter of triangle DEF. Then DH MN and since UIDT A is cyclic we get IDK = IDH = 90 DIU = DUI = IT A D. And since IK IT A = ID = r this implies that lines DH and IT A intersect at K. Mathematical Reflections 4 (016)

Now, since IKD IDT A we have that KD = ID IT A DT A = r DT A IT A. ( ) The line A 1 A passes through O and is perpendicular to BC. So, since UIDT A is cyclic IA A 1 = T A A A 1 = T A UD = T A ID and since A 1 IU = IT A U = 90 we get that A IA 1 = 180 T A IA 1 = 180 T A UI = T A DI. Hence IDT A A 1 IA. From ( ) we have KD = r DT A IA 1 = r = r sin IT A A 1 A and thus K is the midpoint of DH. BAC ( = r cos 90 BAC ) = DH Lemma 1. Let ABC be an arbitrary triangle and let H be its orthocenter. Let O be the circumcenter of triangle ABC and let O be the center of the nine-point circle of triangle ABC (the midpoint of segment OH). Suppose that a point S lies on the nine-point circle of triangle ABC and let l be the line that passes through S such that OS l. If l cuts the circumcircle of triangle ABC at points L, J then the nine-point circle of triangle ALJ passes through the midpoint of AH. Proof of Lemma 1. Let ray HS intersect the circumcircle of triangle ABC at point T. Obviously, HS = ST and LHJT is parallelogram. So LHJ = LT J = 180 BAC. Mathematical Reflections 4 (016) 3

Let A, J 1 and L 1 be the midpoints of segments AH, AL and AJ, respectively. Then J 1 A LH, L 1 A JH and J 1 A L 1 = LHJ = 180 BAC = 180 J 1 P L 1. Hence the points J 1, A, L 1 and P are concyclic. Therefore, the midpoint of AH lies on the ninepoint circle of triangle ALJ, as desired. (See Picture 3 ). This proves Lemma 1. Now, we will use the Lemma 1 and prove the THEOREM. Let P Q (I) = R 1 and P R (I) = Q 1 (See the Picture ). Suppose that after inversion about (I) P P, X X, Y Y, A A. Then P, X, Y, A are the midpoints of segments Q 1 R 1, DR 1, DQ 1 and EF, respectively. We have T A K, (O) (DEF ) 1 where, K be the midpoint of DH and (DEF ) 1 is nine-point circle of the triangle DEF. Obviously, (DEF ) 1 passes through points K and P. And, line Q 1 R 1 passes through P and satisfies IP Q 1 R 1. Therefore from Lemma 1, the point K lies on ninepoint circle of the triangle DQ 1 R 1. So the points K, X, Y and P are concyclic. Hence the points P, T A, X and Y are also concyclic. This completes the proof of THEOREM. References [1] P.Yiu, Mixtilinear incircles, American Mathematical Monthly, Vol. 106, No. 10. (Dec.,1999), pp. 95-955. [] K.L.Nguyen, J.C.Salazar, On Mixtilinear Incircles and excircles, Forum Geometricorum, Vol. 6, 006. [3] C.Pohoata, V.Zajic, On a Mixtilinear Coaxality, Mathematical Reflections, Iss. 1, 01. Mathematical Reflections 4 (016) 4

[4] http://www.artofproblemsolving.com/community/c335h104374 Khakimboy Egamberganov National University of Uzbekistan Tashkent, Uzbekistan E-mail: kh.egamberganov@gmail.com Mathematical Reflections 4 (016) 5

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