# Converse Of The Isosceles Triangle Theorem Review

## Introduction

The isosceles triangle theorem is a fundamental concept in geometry that states that if two sides of a triangle are congruent, then the angles opposite those sides are also congruent. This theorem is widely used in geometric proofs and can help us determine various properties of triangles. In this article, we will review the converse of the isosceles triangle theorem, which is equally important and useful in solving geometric problems.

## Understanding the Converse of the Isosceles Triangle Theorem

The converse of the isosceles triangle theorem states that if two angles of a triangle are congruent, then the sides opposite those angles are also congruent. In other words, if we have a triangle with two congruent angles, we can conclude that the triangle is isosceles and the sides opposite those angles are equal in length.

### Proof of the Converse Theorem

To prove the converse of the isosceles triangle theorem, we can use the concept of the exterior angle of a triangle. Let’s consider a triangle ABC with ∠A≅∠B. We will extend side AB to form an exterior angle at B, which we will call ∠CBD. Since the sum of angles in a triangle is 180 degrees, we can write the equation:

∠A + ∠B + ∠CBD = 180 degrees

Substituting ∠A≅∠B, we get:

∠A + ∠A + ∠CBD = 180 degrees

2∠A + ∠CBD = 180 degrees

Since ∠A and ∠B are congruent, we can rewrite the equation as:

2∠B + ∠CBD = 180 degrees

Now, if we drop a perpendicular from angle C to side AB, let’s call the point of intersection D. Since ∠CBD is an exterior angle, it is equal to the sum of the two opposite interior angles:

∠CBD = ∠C + ∠CDB

Substituting this into our equation, we have:

2∠B + ∠C + ∠CDB = 180 degrees

Since ∠C and ∠CDB are congruent (as they are vertical angles), we can simplify the equation to:

2∠B + 2∠C = 180 degrees

2(∠B + ∠C) = 180 degrees

∠B + ∠C = 90 degrees

From this equation, we can conclude that if two angles of a triangle are congruent, their sum is equal to 90 degrees. This implies that the triangle is isosceles, and the sides opposite those angles are congruent.

## Applications of the Converse Theorem

The converse of the isosceles triangle theorem can be applied in various geometric problems. Here are a few examples:

### Example 1: Finding the Length of a Side

Suppose we have a triangle ABC with angle A = angle B = 60 degrees. Using the converse theorem, we can conclude that the triangle is isosceles and the sides AB and BC are congruent. If we know the length of side AB, we can find the length of side BC by using this information.

Example 2: Proving Triangles Congruent

By applying the converse theorem, we can prove that two triangles are congruent if they have two pairs of congruent angles. This is useful in solving problems involving congruence of triangles.

Example 3: Constructing Isosceles Triangles

If we are given two congruent angles and a side, we can use the converse theorem to construct an isosceles triangle. This construction can be helpful in various geometric constructions.

### 1. What is the converse of the isosceles triangle theorem?

The converse of the isosceles triangle theorem states that if two angles of a triangle are congruent, then the sides opposite those angles are also congruent.

### 2. How do we prove the converse theorem?

The converse of the isosceles triangle theorem can be proven by using the concept of exterior angles and the sum of angles in a triangle.

### 3. What can we conclude from the converse theorem?

If we have a triangle with two congruent angles, we can conclude that the triangle is isosceles and the sides opposite those angles are equal in length.

### 4. How is the converse theorem applied in geometry?

The converse of the isosceles triangle theorem can be applied in various geometric problems, such as finding the length of a side, proving triangles congruent, and constructing isosceles triangles.

### 5. Can the converse theorem be used in other types of triangles?

No, the converse of the isosceles triangle theorem is specific to isosceles triangles. It does not apply to other types of triangles.