10.05 Right triangle congruence

1. There is a rigid motion that will map \angle XYZ to \angle RST because \angle RST \cong \angle XYZ. First, we can rotate \triangle XYZ clockwise about Y until \overline{YZ} \parallel \overline{ST}.

2. Since the transformation is a rigid motion, we have that: \angle XYZ \cong \angle X'Y'Z' \text{, } \overline{XZ} \cong \overline {X'Z'} \text{, and } \overline{YZ} \cong \overline{Y'Z'}

3. Using the given information and the transitive property of congruence, we have that: \angle RST \cong \angle X'Y'Z' \text{, } \overline{RT} \cong \overline {X'Z'} \text{, and } \overline{ST} \cong \overline{Y'Z'}

4. Finally, draw a vector from X to R, and translate \triangle XYZ along the vector. A translation preserves angle measures and side lengths.

We have now shown that:

• X maps to R using rigid motions
• Y maps to S using rigid motions
• Z maps to T using rigid motions

So we have that \triangle XYZ can be mapped onto \triangle RST, so \triangle RST \cong \triangle XYZ.

We also used rigid transformations and the transitive property of congruence to show that triangles were congruent in lesson  5.03 SSS and SAS congruence criteria  and lesson  5.04 ASA and AAS congruence criteria  .

When proving triangles congruent, start by labeling and identifying the given information as well as anything that we can conclude directly from the diagram (such as vertical angles or reflexively congruent parts). Since we are trying to prove two triangles congruent, we need to decide which triangle congruence theorem best fits the given information. Then, when writing the proof we always start with the given information, build any conclusions based on the given information, and end with the conclusion we are trying to prove.

We are given that \overline{LK} \perp \overline{IJ} which means that \angle{IKL} and \angle{JKL} are both right angles by the definition of perpendicular lines. That means \triangle{ILK} and \triangle{JLK} are both right triangles by the definition of right triangles. We are also given that \overline{IL}\cong \overline{JL} which means we have two congruent hypotenuses, and we know that \overline{LK}\cong \overline{LK} by the reflexive property so we have a pair of congruent legs as well. This is enough information to conclude that \triangle{ILK}\cong \triangle{JLK} by the HL theorem.

Triangle proofs can be written in any style - just make sure that each congruent part needed to justify the triangle congruence theorem has its own statement and reason included.

Since m \angle ABC and m \angle CDE = 90 \degree, we know that \triangle ABC and \triangle CDE are both right triangles.

We know that if the hypotenuse and leg of one triangle are congruent to the hypotenuse and leg of another triangle, then the triangles are congruent. We need to choose values for x and y that will make the hypotenuses and the legs congruent.

We can use that \overline{AC} \cong \overline{CE} and \overline{AB} \cong \overline{CD} to solve for the variables. By the definition of congruence, since \overline{AC} \cong \overline{CE} and \overline{AB} \cong \overline{CD}, the two pairs of segments will be equal in length.