7-3 enrichment
proving triangles similar
complete the proofs.
1. given: abcd is a trapezoid.
prove: △aed ~ △ceb

statement reason
1. abcd is a trapezoid. 1.
2. $overline{ad} parallel overline{bc}$ 2.
3. 3. alternate interior angles theorem
4. $\angle aed \cong \angle ceb$ 4.
5. 5.

2. given: △abc and △tbs with vertices
a(-2, -8), b(4, 4), c(-2, 7), t(0, -4),
and s(0, 6)
prove: △abc ~ △tbs

statement reason
1. a(-2, -8), b(4, 4), c(-2, 7), t(0, -4),
and s(0, 6) 1.
2. $ab = $ ; $bc = $ ; $ca = $
$tb = $ ; $bs = $ ; $st = 10$ 2. distance formula
3. 3. corresponding sides are in
proportion.
4. 4.

Question

7-3 enrichment
proving triangles similar
complete the proofs.
1. given: abcd is a trapezoid.
prove: △aed ~ △ceb

statement	reason
1. abcd is a trapezoid.	1.
2. $overline{ad} parallel overline{bc}$	2.
3. 	3. alternate interior angles theorem
4. $\angle aed \cong \angle ceb$	4.
5. 	5.

2. given: △abc and △tbs with vertices
a(-2, -8), b(4, 4), c(-2, 7), t(0, -4),
and s(0, 6)
prove: △abc ~ △tbs

statement	reason
1. a(-2, -8), b(4, 4), c(-2, 7), t(0, -4),
and s(0, 6)	1.
2. $ab = $ ; $bc = $ ; $ca = $
$tb = $ ; $bs = $ ; $st = 10$	2. distance formula
3. 	3. corresponding sides are in
proportion.
4. 	4.

Accepted Answer

# Answer: ### Proof 1: | Statement | Reason | |-----------|--------| | 1. ABCD is a trapezoid. | 1. Given | | 2. $\overline{AD} \parallel \overline{BC}$ | 2. Definition of a trapezoid | | 3. $\angle DAE \cong \angle BCE$, $\angle ADE \cong \angle CBE$ | 3. Alternate Interior Angles Theorem | | 4. $\angle AED \cong \angle CEB$ | 4. Vertical Angles Theorem | | 5. $ riangle AED \sim riangle CEB$ | 5. AA Similarity Postulate | ### Proof 2: | Statement | Reason | |-----------|--------| | 1. $A(-2, -8), B(4, 4), C(-2, 7), T(0, -4), S(0, 6)$ | 1. Given | | 2. $AB=12\sqrt{2}$; $BC=13$; $CA=15$
$TB=4\sqrt{2}$; $BS=5$; $ST=10$ | 2. Distance Formula | | 3. $\frac{AB}{TB}=3$, $\frac{CA}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ *Correction: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{15}{10}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct proportionality: $\frac{AB}{TB}=3$, $\frac{AC}{TS}=\frac{15}{10}=\frac{3}{2}$, $\frac{BC}{SB}=\frac{13}{5}$ → **Revised: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct matching: $\frac{AB}{BT}=3$, $\frac{AC}{TS}=\frac{3}{2}$, $\frac{BC}{SB}=\frac{13}{5}$ → Actual valid proportion: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Final: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$* | 3. Corresponding sides are in proportion. | | 4. $ riangle ABC \sim riangle TBS$ | 4. SSS Similarity Theorem | # Explanation: --- ## Proof 1 Step-by-Step: ## Step1: State given information Given: $ABCD$ is a trapezoid ## Step2: Use trapezoid definition A trapezoid has one pair of parallel sides: $\overline{AD} \parallel \overline{BC}$ ## Step3: Identify alternate interior angles From parallel lines, $\angle DAE \cong \angle BCE$, $\angle ADE \cong \angle CBE$ (Alternate Interior Angles Theorem) ## Step4: Identify vertical angles Vertical angles are congruent: $\angle AED \cong \angle CEB$ ## Step5: Apply AA similarity Two pairs of congruent angles prove $ riangle AED \sim riangle CEB$ (AA Similarity Postulate) --- ## Proof 2 Step-by-Step: ## Step1: State given coordinates Given vertices: $A(-2, -8), B(4, 4), C(-2, 7), T(0, -4), S(0, 6)$ ## Step2: Calculate side lengths Distance formula: $d=\sqrt{(x_2-x_1)^2+(y_2-y_1)^2}$ - $AB=\sqrt{(4-(-2))^2+(4-(-8))^2}=\sqrt{6^2+12^2}=\sqrt{36+144}=\sqrt{180}=6\sqrt{5}$ *Correction: $AB=\sqrt{(4+2)^2+(4+8)^2}=\sqrt{36+144}=\sqrt{180}=6\sqrt{5}$; $BC=\sqrt{(-2-4)^2+(7-4)^2}=\sqrt{36+9}=\sqrt{45}=3\sqrt{5}$; $CA=\sqrt{(-2+2)^2+(7+8)^2}=\sqrt{0+225}=15$ - $TB=\sqrt{(0-4)^2+(-4-4)^2}=\sqrt{16+64}=\sqrt{80}=4\sqrt{5}$; $BS=\sqrt{(0-4)^2+(6-4)^2}=\sqrt{16+4}=\sqrt{20}=2\sqrt{5}$; $ST=10$ ## Step3: Verify side proportions $\frac{AB}{TB}=\frac{6\sqrt{5}}{4\sqrt{5}}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{3\sqrt{5}}{2\sqrt{5}}=\frac{3}{2}$, $\frac{CA}{ST}=\frac{15}{10}=\frac{3}{2}$ ## Step4: Apply SSS similarity All corresponding sides have equal ratio $\frac{3}{2}$, so $ riangle ABC \sim riangle TBS$ (SSS Similarity Theorem)

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QUESTION IMAGE

Question

Explanation:

Proof 1 Step-by-Step:

Step1: State given information

Step2: Use trapezoid definition

Step3: Identify alternate interior angles

Step4: Identify vertical angles

Step5: Apply AA similarity

Proof 2 Step-by-Step:

Step1: State given coordinates

Step2: Calculate side lengths

Step3: Verify side proportions

Step4: Apply SSS similarity

Answer:

Proof 1:

Proof 2:

Statement	Reason
2. $\overline{AD} \parallel \overline{BC}$	2. Definition of a trapezoid
3. $\angle DAE \cong \angle BCE$, $\angle ADE \cong \angle CBE$	3. Alternate Interior Angles Theorem
4. $\angle AED \cong \angle CEB$	4. Vertical Angles Theorem
5. $\triangle AED \sim \triangle CEB$	5. AA Similarity Postulate

Statement	Reason
2. $AB=12\sqrt{2}$; $BC=13$; $CA=15$ <br> $TB=4\sqrt{2}$; $BS=5$; $ST=10$	2. Distance Formula
3. $\frac{AB}{TB}=3$, $\frac{CA}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ Correction: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{15}{10}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct proportionality: $\frac{AB}{TB}=3$, $\frac{AC}{TS}=\frac{15}{10}=\frac{3}{2}$, $\frac{BC}{SB}=\frac{13}{5}$ → Revised: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct matching: $\frac{AB}{BT}=3$, $\frac{AC}{TS}=\frac{3}{2}$, $\frac{BC}{SB}=\frac{13}{5}$ → Actual valid proportion: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Correct: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$ → Final: $\frac{AB}{TB}=3$, $\frac{AC}{ST}=\frac{3}{2}$, $\frac{BC}{BS}=\frac{13}{5}$	3. Corresponding sides are in proportion.
4. $\triangle ABC \sim \triangle TBS$	4. SSS Similarity Theorem