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United States of AmericaPA
High School Core Standards - Geometry Assessment Anchors

7.02 Altitudes, medians, and bisectors of triangles

Lesson

Exploration

The applet below contains a triangle with several special segments drawn. Move the vertex of the triangle around and click the checkboxes to show and hide each special segment type. Let's think about the answers to the following questions.

  1. How might we define each special type of segment?
  2. What properties does each special segment have?
  3. Which segments are always inside the triangle? Which ones are not?
  4. What has to happen for the special segments to coincide?

 

Triangle altitudes

No matter where we move the points of the triangle, the altitude is always a segment that is perpendicular to the base and passes through the vertex.

Altitude

An altitude of a triangle is a segment from any vertex and perpendicular to the line containing the opposite side.

By its definition, the altitude does not need to be inside the triangle. It might even coincide with one of the sides of the triangle.

An altitude may be inside, outside, or one of the sides of a triangle.

 

Triangle medians

No matter where we move the points in the applet, the median is always inside the triangle. The median is the segment that connects one of the vertices of the triangle to the midpoint of the opposite side.

By definition, a median will always be located inside a triangle.

Median

A median of a triangle is a segment whose endpoints are a vertex of the triangle and the midpoint of the opposite side.

 

Angle bisectors of triangles

Recall that an angle bisector is a ray from the vertex of the angle that divides an angle into two congruent angles. This definition holds for the angle bisectors of a triangle. By this definition, an angle bisector will always pass through the vertex of a triangle.

By definition, an angle bisector will always be located inside a triangle.

Perpendicular bisectors of triangles

We can see in the applet above that the perpendicular bisector of a triangle always intersects the midpoint of a side. It's also always at a right angle to it. That's what makes it the perpendicular bisector. However, we can also see that it doesn't always intersect the vertex of the opposite side.

A perpendicular bisector does not necessarily pass through the vertex.

Coinciding special segments

If we move the vertex of the triangle in the applet so that the triangle is isosceles, a special situation occurs. All the special segments overlap!

We can prove that this is true for any isosceles triangle using what we know about congruent triangles and their corresponding parts.

 

Practice questions

Question 1

In the triangle shown below, what does the dashed line represent?

A triangle is depicted with a dashed line connecting a side and its opposite vertex. The side is divided into two segments and are congruent as suggested by the single-hash marks on each divided side.
  1. An angle bisector

    A

    A perpendicular bisector

    B

    An altitude

    C

    A median

    D

Question 2

In the triangle shown below, what does the dashed line represent?

 

  1. An angle bisector.

    A

    A perpendicular bisector.

    B

    An altitude.

    C

    A median.

    D

Question 3

Given $\overline{MQ}$MQ is an altitude to isosceles triangle $MRP$MRP, prove that $\overline{MQ}$MQ is also an angle bisector.

Outcomes

CC.2.3.HS.A.3

Verify and apply geometric theorems as they relate to geometric figures.

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