Angle bisectors of a triangle in I 2



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Mathematical Communications 3(008), 97-05 97 Angle bisectors of a triangle in I Zdenka Kolar Begović,Ružica Kolar Šuper and Vladimir Volenec Abstract. The concept of an angle bisector of the triangle will be introduced in an isotropic plane. Some statements about relationships between the introduced concepts and some other previously studied geometric concepts about triangles will be investigated in an isotropic plane. A number of these statements seems to be new, and some of them are known in Euclidean geometry. Key words: isotropic plane, standard triangle, angle bisector AMS subject classifications: 5N5 Received December, 006 Accepted April 0, 008 Each allowable triangle in an isotropic plane can be set, by a suitable choice of coordinates, into the so-called standard position, i.e. that its circumscribed circle has the equation y = x, and its vertices are of the form A =(a, a ), B =(b, b ), C =(c, c ), where a+b+c = 0. With the labels p = abc, q = bc+ca+ab the equalities q = bc a = ca b = ab c,(c a)(a b) =q 3bc, (a b)(b c) =q 3ca, (b c)(c a) =q 3ab and q = (b + bc + c ) are valid. Theorem. The bisectors of angles A, B, C of the triangle ABC with vertices have the following equations A =(a, a ), B =(b, b ), C =(c, c ) () y = a x + a, y = b x + b, y = c x + c. () They meet the lines BC, CA, AB at the points D, E, F, respectively, with the same ordinate q 3 and with the abscissas d = q 3bc, e = q 3ca, f = q 3ab. (3) 3a 3b 3c Department of Mathematics, University of Osijek, Trg Ljudevita Gaja 6, HR-3 000 Osijek, Croatia, e-mail: zkolar@mathos.hr Faculty of Teacher Education, University of Osijek, Lorenza Jägera 9, HR-3 000 Osijek, Croatia, e-mail: rkolar@ufos.hr Department of Mathematics, University of Zagreb, Bijenička c. 30, HR-0 000 Zagreb, Croatia, e-mail: volenec@math.hr

98 Z. Kolar Begović, R. Kolar Šuper and V. Volenec Proof. According to [5] the lines AB and AC have the equations y = cx ab, y = bx ca, whose addition, because of b + c = a, gives equation y = ax + a, and it is the first equation of (). From that equation and the equation y = ax bc of the line BC we get equation 3 a ax = bc, wherefrom multiplied by, because of a = bc q, follows 3ax = q 3bc with the solution x = d. Besides that solution, from the equation of the line BC for ordinate is got ad bc = 3 (3bc q) bc = q 3. The orthic axis of the triangle ABC has according to [5] the equation y = q 3, wherefrom follows: Corollary. The angle bisectors intersect the opposite sides of the triangle at three points which lie on the orthic axis of the triangle. If the bisectors of the angles of the triangle ABC are understood as their outer bisectors, where their inner bisectors would be the isotropic lines through the points A, B, C, then the role of the intersection of inner bisector has the absolute point of the plane, and the line through the points D, E, F should be called, by the analogy with Euclidean case, antiorthic axis of the triangle ABC. Then Corollary means that orthic and antiorthic axis in an isotropic plane coincide. In Euclidean plane it is not generally the truth, and it holds if and only if the triangle is isosceles. Theorem. Any angle bisector of the triangle intersects its opposite side in the ratio of lengths of its adjacent sides. Proof. Owing to the first equlity (3) we get BD = d b = (q 3bc 3ab) = (3ca q) = (a b)(b c) 3a 3a 3a and similarly CD = (3ab q) = (b c)(c a), 3a 3a and therefore BD CD = a b c a = AB CA. Theorem 3. If A is the bisector of the angle A of the triangle ABC, then the angle (BC,A) is the arithmetic mean of the angles (BC,CA) and (BC,AB). Proof. The lines BC, CA, AB and A have the slopes a, b, c and a,wherefrom and then (BC,A) = a + a = 3 a, (BC,CA) = b + a, (BC,AB) = c + a (BC,CA)+ (BC,AB) =a b c =3a = (BC,A).

Angle bisectors of a triangle in I 99 Theorem 4. The angle bisectors of the triangle ABC determine the triangle A s B s C s, whose vertices are parallel to the points A, B, C and they are the midpoints of the altitudes AA h, BB h, CC h of the triangle ABC. Proof. TheorthictriangleA h B h C h of the triangle ABC with the vertices () has according to [5] the vertices A h =(a, q bc), B h =(b, q ca), C h =(c, q ab). The points A and A h have for the midpoint the first one of the three analogous points A s =(a, bc ), B s =(b, ca ), C s =(c, ab ), (4) because of a + q bc = bc. ThepointA s from (4) lies on the second and third line from () because, for example, for the second line () we get b a + b = bc. The triangle A s B s C s from Theorem 4 will be called symmetral triangle of the triangle ABC. Corollary. The points A s,b s,c s from Theorem 4 lie on the mid-lines of the triangle ABC which are parallel to the lines BC, CA, AB, respectively. Corollary 3. The points A, B, C are the feet of the altitudes of the triangle A s B s C s i.e. the triangle ABC is the orthic triangle of its symmetral triangle. Corollary 4. The symmetral triangle A s B s C s of the standard triangle ABC has the vertices given with (4) and the sides with the equations (). Theorem 5. The symmetral triangle A s B s C s from Theorem 4 is inscribed in the polar circle of the triangle ABC. Proof. The polar circle of the triangle ABC has according to [] the equation y = x q, and the tangent line at the points A s,b s,c s on that circle are the mid-lines of that triangle ABC i.e. the polar circle of triangle is inscribed to its complementary triangle, and the mid-line B m C m has, according to [5] the equation y = ax q + bc. From these two equations the equation for the abscissas of the common points follows x bc q ax + =0. Because of bc q = a this equation is of the form (x a) = 0, and it has double solution x = a which corresponds to the point A s of the line B m C m from Corollary 4. Because of ([6], Corollary 6) and the fact (from Theorem 4) that points A s,b s,c s lie on polar circle and they are the midpoints of the pairs of points A, A h ; B,B h ; C, C h it follows Corollary 5. The points A h,b h,c h from Theorem 4 are inverse images to the points A, B, C with respect to the polar circle of the triangle ABC.

00 Z. Kolar Begović, R. Kolar Šuper and V. Volenec Theorem 6. If any isotropic line meets the lines BC, CA, AB at the points U, V, W, then the centroid of points U, V, W lies on the orthic axis of the triangle ABC. Proof. By the addition of the equations y = ax bc, y = bx ca, y = cx ab of the lines BC, CA, AB we get equation 3y = q of the orthic axis of the triangle ABC. According to [] the contact triangle A i B i C i of the standard triangle ABC, where A i,b i,c i are the touching points of the lines BC, CA, AB with the the inscribed circle of the triangle ABC, has for example the vertex A i =( a, bc q), and according to [5] the triangle ABC has centroid G =(0, 3 q). Because of the first equality (4) the equality A i +A s =3G is valid and according to [5] it means that the point A s is complementary to the point A i in the triangle ABC, i.e. we get the following corollary. Corollary 6. The symmetral triangle A s B s C s of the allowable triangle ABC is complementary triangle to its contact triangle A i B i C i with respect to that triangle. From (4) immediately follows Corollary 7. The symmetral triangle A s B s C s of the standard triangle ABC has the centroid G s =(0, q 6 ). Theorem 7. If the bisector of the angle A meets the line BC at the point D, then the point L isogonal to midpoint L of the segment AD with respect to the triangle ABC lies on the line which joins midpoint of the side BC and the midpoint of the corresponding altitude AA h of that triangle. (The Euclidean version of that theorem is due to MINEUR, [7]). Proof. The point ( q 3bc D =, q ) (5) 3a 3 from the proof of Theorem and the point A =(a, a ) have, according to q 3bc +3a 6a = q 6a = q 3a, the midpoint ( L = q ) 3a, 3a q. (6) 6 For the coordinates x, y of the point L we get successively y x = 3a q 6 q 9a = 8a (9a4 3a q q )= 8a (3a + q)(3a q), xy + qx p = 8a (3a q q ) q 3a p = 8a (5q +3a q +8a bc) = 8a [5q +3a q +8a (a + q)] = 8a (8a4 +a q +5q ) = 8a (3a + q)(6a +5q),

Angle bisectors of a triangle in I 0 px qy y = pq 3a + q 3a q 6 36 (q 6a q +9a 4 ) = 36 [q(a + q) 6(q 3a q)+q 6a q +9a 4 ] = 36 (9a4 +4a q +7q )= 36 (3a + q)(3a +7q), and then, owing to [6], the coordinates of the point L are x = y = xy + qx p y x = a 6a +5q 3a q, px qy y y x = a 3a +7q 3a q. The line which joins the midpoints of the side BC and altitude AA h has according to [4] the equation y = q 3a x q 3 bc. The point L lies on that line because we get y q 3a x = a 3a +7q 3a q + q 3 6a +5q 3a q = 9a4 +9a q 0q 6(3a q) = 6 (3a +5q) = 6 (3bc +q) = q 3 bc. Theorem 8. If the bisectors of the angles A, B, C of the triangle ABC meet respectively the lines BC, CA, AB at the points D, E, F, then the midpoints L, M, N of segments AD, BE, CF lie on one line, which passes through the centroid G of the triangle ABC. Proof. The line with the equation y = 3p q x 3 q (7) passes through the points L, M, N because for example for the point L from (6) we get y + 3p q x = 3a q 3bc 6 6 = 4q 6 = 3 q. The line (7) passes obviously through the centroid G =(0, 3 q). The line (7) is indeed the harmonic polar line of the Gergonne s point Γ of the triangle ABC. Theorem 9. If the bisector of the angle A of the triangle ABC meets the line BC at the point D, then the equality AD BD CD = CA AB (8)

0 Z. Kolar Begović, R. Kolar Šuper and V. Volenec follows. Proof. With d from (3) we get AD = d a = 3a (q 3bc 3a )= (4q 6bc) = (q 3bc) 3a 3a = (c a)(a b), 3a BD = d b = (q 3bc 3ab) = (3ca q) = (a b)(b c) 3a 3a 3a and similarly CD = 3a (b c)(c a), wherefrom AD (c a)(a b) BD CD = 9a [4(c a)(a b) (b c) ] (c a)(a b) = 9a [4ca +4ab 4a (b + c) ] (c a)(a b) = 9a ( 4a 4a a ) = (c a)(a b) = CA AB. Theorem 9 suggests the question under which condition the point D on the line BC will satisfy the equality (8). The answer is the same as at [] in Euclidean case because of Theorem 0. If for the point D on the line BC the equality (8) holds, then either AD is the bisector of the angle A of the triangle ABC or the triangle ABC is isosceles with CA = AB. Proof. Let d be abscissa of the point D. Then AD BD CD + CA AB =(d a) (d b)(d c)+(a c)(b a) =( a + b + c)d + ca + ab bc = 3ad + q 3bc ( = 3a d q 3bc ) 3a and the condition (8) is satisfied if d is given by the formula (3) or if a =0. The condition CA = AB is of the form a c = b a, i.e. a = b + c or 3a = 0, i.e. a =0. Theorem. The angle bisectors of an allowable triangle meet the bisectors of its opposite sides at three points which lie on its circumscribed circle. Proof. For points on the bisector of the side BC is x = a, and with this value, from the equation y = x of the circumscribed circle and y = a x + a of the bisector of the angle A we get the same value y = a 4, and the intersection which is looking for is the point U =( a, a 4 ). Theorem. A circle K through the point A meets circumscribed circle of the triangle ABC and the lines CA and AB once again at the points D, E, F. The segments BC and EF have the same bisector if and only if AD is the bisector of the angle A.

Angle bisectors of a triangle in I 03 Proof. Thecirclewiththeequationy = ux + vx+ w passes through the point A under condition a = a u + av + w, wherefromw = a ( u) av follows, so the circle K has the equation of the form y = ux + vx + a ( u) av. (9) From the equation (9) and the equation y = x of the circumscribed circle we get the equation (u )x + vx + a ( u) av =0,whichcanbewrittenintheform (x a)[(u )(x + a)+v] = 0 with the solutions x = a and x = d, where d = a au v u is the abscissa of the point D. The line AD is bisector of the angle A if and only if the point D is coincident with the point U from proof of Theorem, i.e. under condition a au v = a u. (0) From the equation (9) and the equation y = bx ca of the line CA we get equation ux +(v + b)x a u av ab = 0 because of a + ca = ab. That equation can be writtenintheform(x a)[u(x + a)+v + b] = 0 with solutions x = a and x = e, where e is given by the first equality out of the two analogous equalities e = au + v + b u, f = au + v + c, u while e and f are the abscissas of the points E and F.ThesegmentsBC and EF have the same bisector under condition e + f = b + c, i.e. e + f = a or au +v a u = a. It is easily seen that this condition is coincident with (0). Theorem 3. The angle bisector at the vertex A m of the complementary triangle A m B m C m of the triangle ABC meet the lines CA and AB at the points E a and F a such that the equalities E a A m = AB and F a A m = AC are valid. Proof. Accordingto[5]weget A m = ( a, (q + bc) ). The line with the equation y = a x 3 4 q bc () 4 is parallel to the bisector of the angle A from () and passes through the point A m because of a 4 3 4 q 4 bc = 4 (bc q) 3 4 q 4 bc = (q + bc).

04 Z. Kolar Begović, R. Kolar Šuper and V. Volenec From the equation () and the equation y = bx ca of the line CA we get for the abscissa of the point E a the equation ( a ) + b x = 3 4 q + bc ca. 4 As the right side here is equal to 3 4 (ca b )+ 4 bc ca = 4 c(b a) 3 4 b = 4 (a b ) 3 4 b = ( a )( a ) 4 a b = + b b, it follows e = a b. Andthen E a A m = a ( a b ) = b a = AB. Theorem 4. If E and F are variable points of the lines CA and AB such that CE = BF, then the midpoint of the segment EF scribes bisector at the vertex A m of the complementary triangle of the triangle ABC. (In Euclidean geometry this statement can be found in [3], p. 447 448.) Proof. If CE = BF = t, then the points E and F have abscissas c + t and b + t. From the equation y = bx ca of the line CA for ordinate of the point E we get y = b(c + t) ca = c bt, wherefrom E =(c + t, c bt), and similarly F =(b + t, b ct). The points E and F have midpoint ( t a, a t q ) a. It lies on the line () because of a t q a a ( t a ) + 3 4 q + 4 bc = 4 (bc q a )=0. References [] J. Beban Brkić, V. Volenec, Z. Kolar Begović, R. Kolar Šuper, On Feuerbach s theorem and a pencil of circles in I, Journal for Geometry and Graphics 0(006), 5 3. [] D.R.Byrkit,T.L.Dixon, Some theorems involving the lengths of segments in a triangle, Math. Teacher 80(997), 567 579. [3] F. G. M., Exercises de Géométrie, 5.éd., Maison A. Mame et Fils, Tours 9. [4] Z. Kolar Begović, R. Kolar Šuper, J. Beban Brkić, V. Volenec, Symmedians and symmedian s center of a triangle in an isotropic plane, Mathematica Pannonica 7(006), 87 30.

Angle bisectors of a triangle in I 05 [5] R. Kolar Šuper, Z.Kolar Begović, V. Volenec, J. Beban Brkić, Metrical relationships in standard triangle in an isotropic plane, Mathematical Communications 0(005), 49-57. [6] R. Kolar Šuper, Z. Kolar Begović, V. Volenec, J. Beban Brkić, Isogonality and inversion in an isotropic plane, International Journal of Pure and Applied Mathematics, to appear. [7] A. Mineur, Aproposd unthéorème de M. V. Thébault, Mathesis50(936), 96 98. [8] H. Sachs, Ebene isotrope Geometrie, Vieweg Verlag, Braunschweig/Wiesbaden, 987.

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