11.05 Similarity and congruence in the coordinate plane

The triangles appear to be right triangles. Use the slope formula to confirm the presence of a right angle, then use the HL congruence theorem.

For \triangle{ABC}:

Slope of \overline{AB}: \dfrac{-2-1}{0-0}=\text{undefined}

Slope of \overline{AC}: \dfrac{-2+2}{0-4}=0

Since \overline{AB} is vertical and \overline{AC} is horizontal, they are perpendicular and there is a right angle at \angle{A}.

Using HL for congruence, we calculate the lengths of the hypotenuse and a corresponding pair of legs for each triangle:

Hypotenuse \overline{BC} for triangle ABC = \sqrt{\left( 4-0 \right)^2 \left( -2 + 2 \right)^2}=4

Hypotenuse \overline{YZ} for triangle XYZ = \sqrt{\left( -2+2 \right)^2 + \left(2-5 \right)^2}=4

Leg \overline{AB} for triangle ABC = \sqrt{\left(0-0 \right)^2 + \left(-2-1\right)^2}=3

Leg \overline{XY} for triangle XYZ= \sqrt{\left(-2+2 \right)^2 + \left(2-5\right)^2}=3

Both triangles have a right angle, a leg of length 3 units, and a hypotenuse of length 4 units, making them congruent by the HL theorem.

Suppose we want to prove that the triangles are congruent using an indirect proof, or a proof by contradiction:

Assumption: Assume triangles ABC and XYZ are not congruent.

Based on the coordinate grid, the triangles appear to be right triangles. Let's assume that they are not right triangles to start. By contradiction, we would show that the triangles are in fact right triangles:

For \triangle{ABC}:

Slope of \overline{AB}: \dfrac{-2-1}{0-0}=\text{undefined}

Slope of \overline{AC}: \dfrac{-2+2}{0-4}=0

Since \overline{AB} is vertical and \overline{AC} is horizontal, they are perpendicular.

According to our assumption, this would mean that two triangles having perpendicular sides aren't necessarily right triangles. This is a contradiction to the definition of a right triangle, which states that a right triangle has one angle measuring 90 \degree.

Contradiction with hypotenuse: Given that the hypotenuse \overline{BC} of \triangle{ABC} is 4 units and the hypotenuse \overline{YZ} of triangle \triangle{XYZ} is also 4 units, our assumption would imply that two right triangles with hypotenuses of equal length are not necessarily congruent, which goes against our known properties of right triangles.

Contradiction with leg: Now, the leg \overline{AB} of \triangle{ABC} has a length of 3 units, and the leg \overline{XY} of \triangle{XYZ} also has a length of 3 units. According to our assumption, this would mean that two right triangles with one leg of equal length and hypotenuses of equal length are not necessarily congruent. This is a contradiction to the HL theorem, which states that if the hypotenuse and one leg of one right triangle are congruent to the hypotenuse and one leg of another right triangle, then the two triangles are congruent.

Conclusion: Since our assumption led to a contradiction, it must be false. Therefore, \triangle{ABC} and \triangle{XYZ} are congruent by the HL theorem.

To prove the triangles are similar, we can use the Side-Side-Side (SSS) similarity criterion by showing that the ratios of the corresponding sides of the two triangles are equal. This involves calculating the lengths of the sides using the distance formula.

Draw the triangles on a coordinate grid and label the vertices.

Calculate the lengths of the sides for triangle ABC and triangle PQR, then compare the ratios.

For \triangle ABC:

AB = \sqrt{\left(4-1\right)^2 + \left(6-2\right)^2} = \sqrt{9 + 16} = 5

BC = \sqrt{\left(4-6\right)^2 + \left(6-2\right)^2} = \sqrt{4 + 16} = \sqrt{20}=4\sqrt{5}

CA = \sqrt{\left(6-1\right)^2 + \left(2-2\right)^2} = \sqrt{25} = 5

For \triangle PQR:

PQ = \sqrt{\left(8-2\right)^2 + \left(12-4\right)^2} = \sqrt{36 + 64} = 10

QR = \sqrt{\left(8-12\right)^2 + \left(12-4\right)^2} = \sqrt{16 + 64} = \sqrt{80}=4\sqrt{5}

RP = \sqrt{\left(12-2\right)^2 + \left(4-4\right)^2} = \sqrt{100} = 10

The ratios of the corresponding sides are equal:

\dfrac{AB}{PQ} = \dfrac{5}{10} = \dfrac{1}{2},\,\dfrac{BC}{QR} = \dfrac{2\sqrt{5}}{4\sqrt{5}} = \dfrac{1}{2},\,\dfrac{CA}{RP} = \dfrac{5}{10} = \dfrac{1}{2}

\triangle ABC and \triangle PQR are similar by the SSS similarity criterion.

When showing two non-right triangles are or are not similar, the Side-Side-Side (SSS) similarity criterion is usually easiest.

However, the AA similarity theorem works as well. This theorem requires two pairs of corresponding angles to be congruent, which we can do by identifying transformations and calculating slopes.

For this example, triangle PQR has been dilated by a factor of 2 where the center of dilation is the origin. This means the orientation of the triangles are the same, so the slopes of corresponding sides will be parallel.

Because the corresponding sides of each triangle are parallel, the angles between them are congruent.