Since the triangles are similar with ratio $$3:2$$, corresponding linear dimensions are in the ratio $$3:2$$. The hypotenuse of $$\triangle STU$$ is 8 units, so the hypotenuse of $$\triangle PQR$$ is $$8 \cdot \frac{3}{2} = 12$$ units. Note that areas are in the ratio of the square of the similarity ratio, which would be $$9:4$$, making the area of $$\triangle PQR$$ equal to $$24 \cdot \frac{9}{4} = 54$$ square units, but this doesn't affect the hypotenuse calculation.

The triangle formed by connecting the midpoints of any triangle is similar to the original triangle with a similarity ratio of $$1:2$$. This follows from the theorem that a line connecting midpoints of two sides of a triangle is parallel to the third side and half its length. Since areas of similar figures are in the ratio of the square of the similarity ratio, the area ratio is $$(1/2)^2 = 1/4$$. Therefore, the area of the midpoint triangle is $$60 \cdot \frac{1}{4} = 15$$ square units.

Since $$GH \parallel EF$$, by the theorem about parallel lines in triangles, $$\frac{DG}{DE} = \frac{DH}{DF}$$. We have $$DG = 4$$ and $$GE = 12$$, so $$DE = 16$$. Therefore, $$\frac{DG}{DE} = \frac{4}{16} = \frac{1}{4}$$. Since $$DF = 20$$, we get $$\frac{DH}{20} = \frac{1}{4}$$, so $$DH = 5$$. Therefore, $$FH = DF - DH = 20 - 5 = 15$$.

When you encounter similar triangles, the key insight is that all corresponding sides are proportional by the same scale factor. This means if you know one pair of corresponding sides, you can find the scale factor and determine all other sides.

First, let's find all sides of triangle $$ABC$$. Since it's a right triangle with legs $$AC = 9$$ and $$BC = 12$$, you can use the Pythagorean theorem to find the hypotenuse: $$AB = \sqrt{9^2 + 12^2} = \sqrt{81 + 144} = \sqrt{225} = 15$$. So triangle $$ABC$$ has sides 9, 12, and 15, where 9 is the shortest side and 15 is the longest.

Since triangle $$PQR$$ is similar to triangle $$ABC$$, and the shortest side of triangle $$PQR$$ is 6, you can find the scale factor by comparing shortest sides: $$\frac{6}{9} = \frac{2}{3}$$. This means each side of triangle $$PQR$$ is $$\frac{2}{3}$$ the length of the corresponding side in triangle $$ABC$$.

Therefore, the longest side of triangle $$PQR$$ is $$15 \times \frac{2}{3} = 10$$.

Looking at the wrong answers: A) 8 represents the middle side of triangle $$PQR$$ ($$12 \times \frac{2}{3}$$), not the longest. B) 15 is the longest side of the original triangle $$ABC$$, not the similar triangle. C) 12 is the middle side of triangle $$ABC$$, showing confusion about which triangle we're analyzing.

Remember: when working with similar triangles, always identify the scale factor first by comparing corresponding sides, then apply it consistently to find unknown measurements.

When you encounter a right triangle with an altitude drawn to the hypotenuse, you're dealing with geometric mean relationships. This altitude creates two smaller triangles that are all similar to each other and to the original triangle.

To find the altitude from $$S$$ to hypotenuse $$RT$$, you can use the area method, which is often the most straightforward approach. First, calculate the area of triangle $$RST$$ using the two legs as base and height: Area $$= \frac{1}{2} \times 12 \times 16 = 96$$.

Next, find the hypotenuse using the Pythagorean theorem: $$RT = \sqrt{12^2 + 16^2} = \sqrt{144 + 256} = \sqrt{400} = 20$$.

Now use the fact that the area can also be calculated as $$\frac{1}{2} \times \text{base} \times \text{height}$$, where the base is the hypotenuse and the height is the altitude: $$96 = \frac{1}{2} \times 20 \times h$$. Solving for $$h$$: $$h = \frac{96 \times 2}{20} = \frac{192}{20} = \frac{48}{5}$$.

Looking at the wrong answers: (A) $$\frac{192}{5}$$ occurs if you forget to divide by 2 when using the area formula. (B) $$\frac{96}{5}$$ results from dividing the area by the hypotenuse without accounting for the factor of $$\frac{1}{2}$$. (D) $$\frac{240}{5}$$ comes from incorrectly using $$12 \times 16 = 192$$ as the area instead of $$\frac{1}{2} \times 12 \times 16$$.

Remember: when finding altitude to the hypotenuse, the area method (using both leg calculations and hypotenuse calculation) is typically the most reliable approach.

When you encounter parallel lines intersecting the sides of a triangle, you're dealing with the Side-Splitter Theorem (also called the Triangle Proportionality Theorem). This theorem states that if a line is parallel to one side of a triangle and intersects the other two sides, it divides those sides proportionally.

First, let's find the slope of line $$BC$$. With $$B(8, 0)$$ and $$C(0, 6)$$, the slope is $$\frac{6-0}{0-8} = -\frac{3}{4}$$. Since line $$PQ$$ is parallel to $$BC$$, it has the same slope.

Now apply the proportionality relationship. Point $$P(5, 0)$$ divides $$AB$$ in the ratio $$AP:PB = 5:3$$ (since $$AP = 5$$ and $$PB = 3$$). By the Side-Splitter Theorem, point $$Q$$ must divide $$AC$$ in the same ratio $$5:3$$.

Since $$AC$$ has length 6 (from $$(0,0)$$ to $$(0,6)$$), and $$Q$$ divides it in ratio $$5:3$$, we have $$AQ = \frac{5}{5+3} \times 6 = \frac{5}{8} \times 6 = \frac{15}{4}$$. Therefore, $$Q = \left(0, \frac{15}{4}\right)$$, which is answer C.

Answer A gives $$\frac{8}{15}$$, which incorrectly flips the ratio. Answer B gives $$\frac{15}{8}$$, which uses the correct numbers but in the wrong fraction form. Answer D gives $$\frac{4}{15}$$, which represents the complement ratio error.

Strategy tip: For parallel line problems in triangles, always identify the ratio on one side first, then apply that same ratio to find the corresponding division on the other side.

Since $$DE \parallel BC$$, by the theorem about parallel lines in triangles, $$\frac{AD}{AB} = \frac{AE}{AC} = \frac{DE}{BC}$$. We have $$AD = 6$$ and $$DB = 9$$, so $$AB = 15$$. The ratio is $$\frac{AD}{AB} = \frac{6}{15} = \frac{2}{5}$$. Since $$AE = 8$$, we get $$AC = \frac{8}{2/5} = 20$$, so $$EC = 12$$. Also, $$DE = \frac{2}{5} \cdot BC$$. The perimeter of $$\triangle ABC$$ is $$AB + AC + BC = 15 + 20 + BC = 45$$, so $$BC = 10$$ and $$DE = 4$$. The perimeter of $$\triangle ADE$$ is $$6 + 8 + 4 = 18$$.

When you encounter similar triangles with given ratios, you're working with proportional relationships where corresponding sides maintain the same scale factor throughout.

The first triangle has sides in the ratio $$5:12:13$$. Since $$5^2 + 12^2 = 25 + 144 = 169 = 13^2$$, this confirms it's a right triangle where 5 is the shortest side, 12 is the middle side, and 13 is the hypotenuse (longest side).

For the similar triangle with shortest side 15 units, you need to find the scale factor. Since the shortest sides correspond, set up the proportion: $$\frac{15}{5} = 3$$. This means the second triangle is 3 times larger than the first.

Multiply each side of the original triangle by 3:

• Shortest side: $$5 \times 3 = 15$$
• Middle side: $$12 \times 3 = 36$$
• Longest side: $$13 \times 3 = 39$$

The difference between longest and shortest sides is $$39 - 15 = 24$$ units.

Looking at the wrong answers: (A) 36 represents the middle side length, not the difference between longest and shortest. (B) 27 might result from incorrectly calculating $$39 - 12 = 27$$, using the wrong sides. (C) 30 could come from miscalculating the scale factor or the proportional relationships.

Strategy tip: With similar triangles, always identify the scale factor first by comparing corresponding sides, then apply it consistently to all dimensions. Double-check by verifying the ratios remain constant across both triangles.