5 blog notes congruent triangles

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The Concept of Congruence

Congruence - Congruent

You walk into your favorite mall and see dozens of copies of your favorite CD on sale. All of the

CDs are exactly the same size and shape.

In fact, you can probably think of many objects that are mass produced to be exactly the same size and shape.

Objects that are exactly the same size and shape are said to be congruent.

Congruent objects are duplicates of one another.

If two mathematical figures are congruent and you cut one figure out with a pair of scissors, it will fit perfectly on top of the other figure.

Mathematicians use the word congruent to describe geometrical figures.

-- If two quadrilaterals (4 sided) are the same size and shape,

they are congruent.

-- If two pentagons (5 sided) are the same size and shape,

they are congruent.

-- If two polygons (any number of sides) are the same size and shape,

they are congruent.

-- If two line segments are the same length (they already are the same

shape), they are congruent.

The mathematical symbol used to denote congruent is .

The symbol is made up of two parts: which means the same shape (similar) and which means the same size (equal).

Congruent

Symbol

When you are looking at congruent figures, be sure to find the sides and the angles that "match up" (are in the same places) in each figure. Sides and angles that "match up" are called corresponding sides and corresponding angles .

In congruent figures, these corresponding parts are also congruent.

The corresponding sides will be equal in measure (length) and that the corresponding angles will be equal in degrees.

Theorems for Congruent

Triangles

Latest news bulletin:

The most popular congruent figures are triangles!

In many geometrical proofs, it may be necessary to prove that two triangles are congruent to each other. The task may simply be to prove the triangles congruent, or it may be to use these congruent triangles to gain additional information.

When triangles are congruent and one triangle is placed on top of the other, the sides and angles that coincide (are in the same positions) are called corresponding parts.

Example:

When two triangles are congruent, there are

6 facts that are true about the triangles:

 the triangles have 3 sets of congruent

(of equal length) sides and the triangles have 3 sets of congruent

(of equal measure) angles .

NOTE: The corresponding congruent sides are marked with small straight line segments called hash marks .

The corresponding congruent angles are marked with arcs.

The 6 facts for our congruent triangles example:

Note:

The order of the letters in the names of the triangles should display the corresponding relationships. By doing so, even without a picture, you would know that < A would be congruent to

< D

, and would be congruent to , because they are in the same position in each triangle name.

Wow! Six facts for every set of congruent triangles!

Fortunately, when we need to PROVE (or show) that triangles are congruent, we do NOT need to show all six facts are true. There are certain combinations of the facts that are sufficient to prove that triangles are congruent. These combinations of facts guarantee that if a triangle can be drawn with this information, it will take on only one shape. Only one unique triangle can be created, thus guaranteeing that triangles created with this method are congruent.

SSS

Methods for Proving (Showing) Triangles to be Congruent

If three sides of one triangle are congruent to three sides of another triangle, the triangles are congruent.

(For this method, the sum of the lengths of any two sides must be greater than the length of the third side, to guarantee a triangle exists.)

SAS If two sides and the included angle of one triangle are congruent to the corresponding parts of another triangle, the triangles are congruent. (The included angle is the angle formed by the sides being used.

)

ASA If two angles and the included side of one triangle are congruent to the corresponding parts of another triangle, the triangles are congruent. (The included side is the side between the angles being used. It is the side where the rays of the angles would overlap.)

AAS If two angles and the non-included side of one triangle are congruent to the corresponding parts of another triangle, the triangles are congruent. (The non-included side can be either of the two sides that are not between the two angles being used.)

HL

Right

Triangles

Only

If the hypotenuse and leg of one right triangle are congruent to the corresponding parts of another right triangle, the right triangles are congruent. (Either leg of the right triangle may be used as long as the corresponding legs are used.)

BE CAREFUL!!!

Only the combinations listed above will give congruent triangles.

So, why do other combinations not work?

AAA

Methods that

DO NOT

Prove Triangles to be Congruent

AAA works fine to show that triangles are the same SHAPE (similar), but does NOT work to also show they are the same size, thus congruent!

You can easily draw 2 equilateral triangles that are the same shape but are not congruent (the same size).

Consider the example at the right.

SSA or

ASS

SSA (or ASS) is humorously referred to as the "Donkey Theorem".

This is NOT a universal method to prove triangles congruent because it cannot guarantee that one unique triangle will be drawn!!

The SSA (or ASS) combination affords the possibility of creating zero, one, or two triangles. Consider this diagram of triangle

DEF . If for the second side, EF is equal to EG (the minimum distance needed to create a triangle) , only one triangle can be drawn.

However, if EF is greater than EG , two triangles can be drawn as shown by the dotted segment. Should EF be less than the minimum length needed to create a triangle, EG, no triangle can be drawn.

The possible "swing" of side can create two different triangles which causes our problem with this method. The first triangle, below, and the last triangle both show

SSA, but they are not congruent triangles.

The combination of SSA (or ASS) creates a unique triangle ONLY when working in a right triangle with the hypotenuse and a leg. This application is given the name HL

(Hypotenuse-Leg) for Right Triangles to avoid confusion. You should not list SSA

(or ASS) as a reason when writing a proof.

Once you prove your triangles are congruent, the "left-over" pieces that were not used in your method of proof, are also congruent.

Remember, congruent triangles have 6 sets of congruent pieces. We now have a "follow-up" theorem to be used AFTER the triangles are known to be congruent:

Theorem: (CPCTC) Corresponding parts of congruent triangles are congruent.

Two triangles are congruent if all pairs of corresponding sides are congruent, and all pairs of corresponding angles are congruent. Fortunately, we do not need to show all six of these congruent parts each time we want to show triangles congruent. There are 5 combination methods that allow us to show triangles to be congruent.

Tips for Working with

Congruent Triangles in Proofs

Remember to look for ONLY these combinations for congruent triangles:

SAS, ASA, SSS, AAS, and HL

(right triangle)

But how do we decide which method we should be using?

Let's look at some examples and tips:

Example 1:

Here is an example problem, using one of the methods mentioned above.

Which congruent triangle method do you think

:

Prove:

Answ er is used in this example?

Did you notice that the congruent triangle parts that were given to us were marked up in the diagram? This technique is very helpful when trying to decide which method of congruent triangles to use.

TIP: Mark any given information on your diagram.

Mark diagram

Example 2:

In this example problem, examine the given information, mark the given information on the diagram as in the first tip, and decide if congruent triangles will help you solve this problem.

Prove :

:

This problem does not ask you to prove the triangles are congruent. This, however, does not mean that you should not "look" for congruent triangles in this problem. Remember that once two triangles are congruent, their "left-over" corresponding pieces are also congruent. If you can prove these two triangles are congruent, you will be able to prove that the segments you need are also congruent since they will be "leftover" corresponding pieces.

Which of the congruent triangle methods

Answ er do you think is used in this example?

For the triangles in this second example, three sets of corresponding parts were used to prove the triangles congruent. Can you name the other 3 sets of corresponding parts?

CLICK HERE to see the answer.

Corresponding

Parts

TIP: Look to see if the pieces you need are "parts" of the triangles that can be proven congruent.

Example 3:

In this example problem, examine the given information, decide what else you need to know, and then decide the proper method to be used to prove the triangles congruent.

Prove:

There seems to be missing information in this problem. There are only two pieces of congruent information given. This problem expects you to "find" the additional information you will need to show that the triangles are congruent. What else do you notice is true in this picture?

Answ er

Which of the congruent triangle methods do you think is used in this example?

Examine

Diagram

TIP: If not given all needed pieces to prove the triangles congruent, look to see what else you might know about the diagram.

Example 4:

In this example problem, examine the given information carefully, mark up the diagram and then decide upon the proper method to be used to prove the triangles congruent.

When you marked up the diagram, did you mark the information gained from the definition of the angle bisector? While this problem only gives you two of the three sets of congruent pieces needed to prove the triangles congruent, it also gives you a "hint" as to how to obtain the third needed set. The "hint" in this problem is in the form of a definition - the angle bisector.

Answ er

Which of the congruent triangle methods do you think is used in this example?

Use Definitions

TIP: Know your definitions! If the given information contains definitions, consider these as

"hints" to the solution and be sure to use them.

This particular example can be solved in more than one way.

Even though the given information gives congruent information about <B and <D, this information is not needed to prove the triangles congruent. The two triangles in this problem "share" a side (called a common side). This "sharing" automatically gives you another set of congruent pieces.

More than one solution

TIP: Stay open-minded. There may be more than one way to solve a problem.

Common Parts

TIP: Look to see if your triangles "share" parts.

These common parts are automatically one set of congruent parts.

In summary, when working with congruent triangles, remember to:

1.

Mark any given information on your diagram.

2.

Look to see if the pieces you need are "parts" of the triangles that can be proven congruent.

3.

If not given all needed pieces to prove the triangles congruent, look to see what else you might know about the diagram.

4.

Know your definitions! If the given information contains definitions, consider these as

"hints" to the solution and be sure to use them.

5.

Stay open-minded. There may be more than one way to solve a problem.

6.

Look to see if your triangles "share" parts. These common parts are automatically one set of congruent parts.

Remember that proving triangles congruent is like solving a puzzle. Look carefully at the

"puzzle" and use all of your geometrical strategies to arrive at an answer.

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