Lesson Medians in an isosceles triangle
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<H2>Medians in an isosceles triangle</H2> It is better to read this lesson after the lessons <A HREF=http://www.algebra.com/algebra/homework/Triangles/Congruence-tests-for-triangles.lesson> Congruence tests for triangles</A> and <A HREF=http://www.algebra.com/algebra/homework/Triangles/Isosceles-triangles.lesson> Isosceles triangles</A> that are under the topic <B>Triangles</B> in the section <B>Geometry</B> in this site. <B>Theorem 1</B> If a triangle is isosceles, then the two medians drawn from vertices at the base to the sides are of equal length. <TABLE> <TR> <TD> <B>Proof</B> Let <B>ABC</B> be an isosceles triangle with sides <B>AC</B> and <B>BC</B> of equal length (<B>Figure 1</B>). We need to prove that the medians <B>AD</B> and <B>BE</B> are of equal length. Consider the triangles <B>ADC</B> and <B>BEC</B>. They have two congruent sides that include congruent angles. Indeed, <B>AC</B> = <B>BC</B> by the condition, because the triangle <B>ABC</B> is isosceles. Since the lateral sides <B>AC</B> and <B>BC</B> are of equal length, their halves <B>EC</B> and <B>DC</B> are of equal length too: <B>EC</B> = <B>DC</B>. Finally, the angle <B>ECD</B> is the common angle. Thus, the triangles <B>ADC</B> and <B>BEC</B> are congruent, in accordance to the <B>postulate P1 (SAS)</B> (see the lesson <A HREF=http://www.algebra.com/algebra/homework/Triangles/Congruence-tests-for-triangles.lesson> Congruence tests for triangles</A> of the topic <B>Triangles</B> in the section <B>Geometry</B> in this site). Hence, the medians <B>AD</B> and <B>BE</B> are of equal length as the corresponding sides of these triangles. The proof is completed. </TD> <TD> {{{drawing( 200, 250, 0, 4, 0, 5, line( 0.3, 0.5, 3.7, 0.5), line( 0.3, 0.5, 2.0, 4.5), line( 2.0, 4.5, 3.7, 0.5), locate(0.3, 0.5, A), locate(3.7, 0.5, B), locate(2.0, 4.9, C), line (0.3, 0.5, 2.85, 2.5), line (3.7, 0.5, 1.15, 2.5), locate(2.9, 2.7, D), locate(0.9, 2.7, E), line (1.35, 3.2, 1.55, 3.2), line (1.35, 3.3, 1.55, 3.3), line (2.45, 3.2, 2.65, 3.2), line (2.45, 3.3, 2.65, 3.3), line (0.8, 1.8, 1.0, 1.8), line (0.8, 1.9, 1.0, 1.9), line (0.8, 2.0, 1.0, 2.0), line (3.0, 1.8, 3.2, 1.8), line (3.0, 1.9, 3.2, 1.9), line (3.0, 2.0, 3.2, 2.0), arc ( 2.0, 4.5, 0.8, 0.8, 70, 110), arc ( 2.0, 4.5, 1.0, 1.0, 70, 110) )}}} <B>Figure 1</B>. To the <B>Theorem 1</B> </TD> </TR> </TABLE> The opposite statement to the <B>Theorem 1</B> is true also. <B>Theorem 2</B> If in a triangle the two medians drawn from vertices at the base to the sides are of equal length, then the triangle is isosceles. <TABLE> <TR> <TD> <B>Proof</B> Let <B>ABC</B> be a triangle with medians <B>AD</B> and <B>BE</B> of equal length (<B>Figure 2</B>). We need to prove that the sides <B>AC</B> and <B>BC</B> are of equal length. Connect the points <B>E</B> and <B>D</B> by the straight line segment <B>ED</B> (<B>Figure 3</B>). Since the points <B>E</B> and <B>D</B> are midpoints of the sides <B>AC</B> and <B>BC</B>, the straight line <B>ED</B> is parallel to the triangle side <B>AB</B>. It is proved in the lesson <A HREF=http://www.algebra.com/algebra/homework/Triangles/The-line-segment-joining-the-midpoints-of-two-sides-of-a-triangle.lesson> The line segment joining the midpoints of two sides of a triangle</A> (under the topic <B>Triangles</B> in the section <B>Geometry</B> in this site). Draw the straight line from the point <B>E</B> parallel to the median <B>AD</B> till the intersection with the continuation of the straight line <B>AB</B> (<B>Figure 3</B>). Mark the intersection point as <B>F</B>. Also connect the points <B>F</B> and <B>A</B>. Since in the quadrilateral <B>FADE</B> the opposite sides <B>FA</B> and <B>ED</B> are parallel and the opposite sides <B>FE</B> and <B>AD</B> are parallel too, the segment <B>FE</B> </TD> <TD> {{{drawing( 200, 250, 0, 4, 0, 5, line( 0.3, 0.5, 3.7, 0.5), line( 0.3, 0.5, 2.0, 4.5), line( 2.0, 4.5, 3.7, 0.5), locate(0.3, 0.5, A), locate(3.7, 0.5, B), locate(2.0, 4.9, C), line (0.3, 0.5, 2.85, 2.5), line (3.7, 0.5, 1.15, 2.5), locate(2.9, 2.7, D), locate(0.9, 2.7, E), line (1.35, 1.35, 1.55, 1.35), line (1.35, 1.42, 1.55, 1.42), line (2.45, 1.35, 2.65, 1.35), line (2.45, 1.42, 2.65, 1.42) )}}} <B>Figure 2</B>. To the <B>Theorem 2</B> </TD> <TD> {{{drawing( 300, 250, -2, 4, 0, 5, line( 0.3, 0.5, 3.7, 0.5), line( 0.3, 0.5, 2.0, 4.5), line( 2.0, 4.5, 3.7, 0.5), locate(0.3, 0.5, A), locate(3.7, 0.5, B), locate(2.0, 4.9, C), line (0.3, 0.5, 2.85, 2.5), line (3.7, 0.5, 1.15, 2.5), locate(2.9, 2.7, D), locate(0.9, 2.7, E), line (1.35, 1.35, 1.55, 1.35), line (1.35, 1.42, 1.55, 1.42), line (2.45, 1.35, 2.65, 1.35), line (2.45, 1.42, 2.65, 1.42), green(line (1.15, 2.5, 2.85, 2.5)), green(line (-1.4, 0.5, 1.15, 2.5)), locate(-1.4, 0.5, F), green(line (-1.4, 0.5, 0.3, 0.5)), arc(0.3, 0.5, 0.8, 0.8, 325, 360), arc(-1.4, 0.5, 0.8, 0.8, 325, 360), arc( 3.7, 0.5, 0.8, 0.8, 180, 220) )}}} <B>Figure 3</B>. To the proof of the <B>Theorem 2</B> </TD> </TR> </TABLE>is of the same length as the median <B>AD</B>. It is proved in the lesson <A HREF=http://www.algebra.com/algebra/homework/Triangles/Properties-of-the-sides-of-parallelograms.lesson> Properties of the sides of parallelograms</A> under the topic <B>Triangles</B> in the section <B>Geometry</B> in this site. This means that the segment <B>FE</B> is of the same length as <B>BE</B>, because the medians <B>AD</B> and <B>BE</B> are of equal length. So, the triangle <B>FBE</B> is isosceles and its angles <B>BFE</B> and <B>FBE</B> are congruent. This implies that the angles <B>BAD</B> and <B>ABE</B> are congruent, because the angles <B>BFE</B> and <B>BAD</B> are congruent as the corresponding angles at parallel straight lines <B>FE</B> and <B>AD</B> (see the lesson <A HREF=http://www.algebra.com/algebra/homework/Angles/Parallel-lines.lesson> Parallel lines</A> under the topic <B>Angles, complementary, supplementary angles</B> in the section <B>Geometry</B> in this site). Now, you have two triangles <B>ABE</B> and <B>BAD</B> with the common base <B>AB</B>, with the congruent lateral sides <B>AD</B> and <B>BE</B>, and with the congruent angles <B>BAD</B> and <B>ABE</B> that are included between congruent sides. In accordance to the <B>postulate P1 (SAS)</B> of the lesson <A HREF=http://www.algebra.com/algebra/homework/Triangles/Congruence-tests-for-triangles.lesson> Congruence tests for triangles</A> (under the topic <B>Triangles</B> in the section <B>Geometry</B> in this site), these triangles are congruent. This implies that the corresponding sides <B>AE</B> and <B>BD</B> are congruent, and hence the lateral sides <B>AC</B> and <B>BC</B> are of equal length, because their lengths are twice the lengths of the segments <B>AE</B> and <B>BD</B>. The proof is completed. <B>Summary</B> <B>A triangle is isosceles if and only if the two medians drawn from vertices at the base to the sides are of equal length</B>. Similar statements are valid for altitudes and angle bisectors of the isosceles triangle: <B>A triangle is isosceles if and only if the two altitudes drawn from vertices at the base to the sides are of equal length</B>. <B>If a triangle is isosceles, then two angle bisectors drawn from vertices at the base to the sides are of equal length</B>. The proofs are similar to that for the medians of the current lesson. Try to prove these statements yourself. In any case, you can find the full proofs in the lessons <A HREF=http://www.algebra.com/algebra/homework/word/geometry/Altitudes-in-an-isosceles-triangle.lesson> Altitudes in an isosceles triangle</A> and <A HREF=http://www.algebra.com/algebra/homework/word/geometry/Angle-bisectors-in-an-isosceles-triangle.lesson> Angle bisectors in an isosceles triangle</A> under the current topic (the topic <B>Geometry</B> in the section <B>Word problems</B>). For your convenience, below is the list of my relevant lessons in this site in the logical order. <A HREF=http://www.algebra.com/algebra/homework/Triangles/Congruence-tests-for-triangles.lesson>Congruence tests for triangles</A> under the topic <B>Triangles</B> in the section <B>Geometry</B>; <A HREF=http://www.algebra.com/algebra/homework/Triangles/Isosceles-triangles.lesson>Isosceles triangles</A> under the topic <B>Triangles</B> in the section <B>Geometry</B>; <A HREF=http://www.algebra.com/algebra/homework/Triangles/An-altitude-a-median-and-an-angle-bisector-in-the-isosceles-triangle.lesson>An altitude, a median and an angle bisector in the isosceles triangle</A> under the topic <B>Triangles</B> in the section <B>Geometry</B>; <A HREF=http://www.algebra.com/algebra/homework/word/geometry/Altitudes-in-an-isosceles-triangle.lesson>Altitudes in an isosceles triangle</A> under the topic <B>Geometry</B> in the section <B>Word problems</B>; <A HREF=http://www.algebra.com/algebra/homework/Triangles/The-line-segment-joining-the-midpoints-of-two-sides-of-a-triangle.lesson>The line segment joining the midpoints of two sides of a triangle</A> under the topic <B>Triangles</B> in the section <B>Geometry</B> (the auxiliary material to the present lesson); <A HREF=http://www.algebra.com/algebra/homework/Triangles/Properties-of-the-sides-of-parallelograms.lesson>Properties of the sides of parallelograms</A> under the topic <B>Triangles</B> in the section <B>Geometry</B> (the auxiliary material to the present lesson); <A HREF=http://www.algebra.com/algebra/homework/word/geometry/Angle-bisectors-in-an-isosceles-triangle.lesson>Angle bisectors in an isosceles triangle</A> under the topic <B>Geometry</B> in the section <B>Word problems</B>. For navigation over the lessons on Properties of Triangles use this file/link <A HREF=https://www.algebra.com/algebra/homework/Triangles/Compendium-of-properties-of-triangles.lesson>Properties of Trianles</A>. To navigate over all topics/lessons of the Online Geometry Textbook use this file/link <A HREF=https://www.algebra.com/algebra/homework/Triangles/GEOMETRY-your-online-textbook.lesson>GEOMETRY - YOUR ONLINE TEXTBOOK</A>.
