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Important CBSE-style practice questions on Heron’s Formula
Important CBSE-style practice questions on Heron’s Formula
## **Solution 1: Find the Area of a Triangle (Basic Calculation)**
📌 **Question:**
Find the area of a triangle with sides **9 cm, 12 cm, and 15 cm** using Heron’s formula.
### **Step 1: Find the Semi-Perimeter (s)**
\[
s = \frac{a + b + c}{2} = \frac{9 + 12 + 15}{2} = \frac{36}{2} = 18 \text{ cm}
\]
### **Step 2: Apply Heron’s Formula**
\[
\text{Area} = \sqrt{s(s-a)(s-b)(s-c)}
\]
\[
= \sqrt{18(18-9)(18-12)(18-15)}
\]
\[
= \sqrt{18 \times 9 \times 6 \times 3}
\]
\[
= \sqrt{2916}
\]
\[
= 54 \text{ cm}^2
\]
✅ **Final Answer: 54 cm²**
—
## **Solution 2: Find the Cost of Paving a Triangular Garden**
📌 **Question:**
A **triangular garden** has sides **80 m, 90 m, and 100 m**. Find the cost of paving the garden at ₹20 per square meter.
### **Step 1: Find the Semi-Perimeter (s)**
\[
s = \frac{80 + 90 + 100}{2} = \frac{270}{2} = 135 \text{ m}
\]
### **Step 2: Apply Heron’s Formula**
\[
\text{Area} = \sqrt{135(135-80)(135-90)(135-100)}
\]
\[
= \sqrt{135 \times 55 \times 45 \times 35}
\]
Using calculations:
\[
= \sqrt{31185000} \approx 5587.5 \text{ m}^2
\]
### **Step 3: Find the Total Cost**
\[
\text{Cost} = \text{Area} \times \text{Rate per m}^2
\]
\[
= 5587.5 \times 20
\]
\[
= 1,11,750
\]
✅ **Final Answer: ₹1,11,750**
—
## **Solution 3: Finding the Height of a Triangle**
📌 **Question:**
A triangle has a **base of 14 cm** and an **area of 84 cm²**. Find its height.
### **Step 1: Use the Basic Area Formula**
\[
\text{Area} = \frac{1}{2} \times \text{Base} \times \text{Height}
\]
\[
84 = \frac{1}{2} \times 14 \times h
\]
### **Step 2: Solve for Height (h)**
\[
h = \frac{84 \times 2}{14} = \frac{168}{14} = 12 \text{ cm}
\]
✅ **Final Answer: Height = 12 cm**
—
## **Solution 4: Finding the Area of a Right-Angled Triangle**
📌 **Question:**
Find the area of a **right-angled triangle** whose **hypotenuse is 13 cm** and one of the sides is **5 cm**, using Heron’s formula.
### **Step 1: Use Pythagoras Theorem to Find the Third Side**
\[
\text{Hypotenuse}^2 = \text{Base}^2 + \text{Height}^2
\]
\[
13^2 = 5^2 + h^2
\]
\[
169 = 25 + h^2
\]
\[
h^2 = 169 – 25 = 144
\]
\[
h = 12 \text{ cm}
\]
✅ So, the sides of the triangle are **5 cm, 12 cm, and 13 cm**.
### **Step 2: Find the Semi-Perimeter (s)**
\[
s = \frac{5 + 12 + 13}{2} = \frac{30}{2} = 15 \text{ cm}
\]
### **Step 3: Apply Heron’s Formula**
\[
\text{Area} = \sqrt{15(15-5)(15-12)(15-13)}
\]
\[
= \sqrt{15 \times 10 \times 3 \times 2}
\]
\[
= \sqrt{900} = 30 \text{ cm}^2
\]
✅ **Final Answer: 30 cm²**
—
## **Solution 5: Quadrilateral Divided into Two Triangles**
📌 **Question:**
A **quadrilateral** is divided into two triangles with sides **6 cm, 8 cm, 10 cm** and **5 cm, 12 cm, 13 cm**. Find its total area using Heron’s formula.
### **Step 1: Find the Area of Triangle 1 (6 cm, 8 cm, 10 cm)**
**Semi-Perimeter:**
\[
s = \frac{6+8+10}{2} = \frac{24}{2} = 12 \text{ cm}
\]
\[
\text{Area} = \sqrt{12(12-6)(12-8)(12-10)}
\]
\[
= \sqrt{12 \times 6 \times 4 \times 2}
\]
\[
= \sqrt{576} = 24 \text{ cm}^2
\]
✅ **Triangle 1 Area = 24 cm²**
—
### **Step 2: Find the Area of Triangle 2 (5 cm, 12 cm, 13 cm)**
**Semi-Perimeter:**
\[
s = \frac{5+12+13}{2} = \frac{30}{2} = 15 \text{ cm}
\]
\[
\text{Area} = \sqrt{15(15-5)(15-12)(15-13)}
\]
\[
= \sqrt{15 \times 10 \times 3 \times 2}
\]
\[
= \sqrt{900} = 30 \text{ cm}^2
\]
✅ **Triangle 2 Area = 30 cm²**
—
### **Step 3: Total Area of the Quadrilateral**
\[
= 24 + 30 = 54 \text{ cm}^2
\]
✅ **Final Answer: 54 cm²**
—
## **📌 Summary of Important Exam Tips**
✔ **Always find the semi-perimeter first.**
✔ **Check for right-angled triangles using Pythagoras’ theorem.**
✔ **If given a quadrilateral, split it into two triangles.**
✔ **Always include the correct units (cm², m², etc.) for full marks.**
—
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February 5, 2025
CBSE style practice questions for Heron’s Formula based on past exam patterns
CBSE style practice questions for Heron’s Formula based on past exam patterns
### **📌 Section A: Basic Questions (1-2 Marks Each)**
1️⃣ Find the area of a triangle whose sides are **9 cm, 12 cm, and 15 cm** using Heron’s formula.
2️⃣ A triangle has sides **5 cm, 12 cm, and 13 cm**. Calculate its area.
3️⃣ Find the semi-perimeter of a triangle with sides **18 cm, 24 cm, and 30 cm**.
4️⃣ A triangle has a perimeter of **40 cm**. Two of its sides are **15 cm and 12 cm**. Find the third side if the area is **80 cm²**.
5️⃣ If the sides of a triangle are in the ratio **3:4:5** and its perimeter is **36 cm**, find its area.
—
### **📌 Section B: Intermediate-Level Questions (3-4 Marks Each)**
6️⃣ A triangular park has sides **40 m, 50 m, and 60 m**. Find the area of the park and the cost of laying grass at ₹5 per square meter.
7️⃣ Find the height of a triangle with **base = 14 cm** and **area = 84 cm²** using Heron’s formula.
8️⃣ A triangle has sides **7 cm, 8 cm, and 9 cm**. Find the **difference** between its area using Heron’s formula and using the base-height formula.
9️⃣ Find the area of a **right-angled triangle** whose hypotenuse is **13 cm** and one of the sides is **5 cm**, using Heron’s formula.
🔟 A farmer has a **triangular field** with sides **26 m, 28 m, and 30 m**. He wants to fence it with three rounds of wire. If the cost of fencing is ₹15 per meter, find the total fencing cost.
—
### **📌 Section C: Higher Order Thinking (HOTs) Questions (5-6 Marks Each)**
1️⃣1️⃣ A **quadrilateral** is divided into **two triangles** with sides **6 cm, 8 cm, 10 cm** and **5 cm, 12 cm, 13 cm**. Find its total area using Heron’s formula.
1️⃣2️⃣ The sides of a triangular garden are **80 m, 90 m, and 100 m**. Find the cost of **paving** the garden with tiles at ₹20 per square meter.
1️⃣3️⃣ A **trapezium** is divided into two triangles of sides **10 cm, 12 cm, 14 cm** and **8 cm, 15 cm, 17 cm**. Find the total area of the trapezium.
1️⃣4️⃣ Find the area of an **isosceles triangle** with base **24 cm** and equal sides **26 cm** using Heron’s formula.
1️⃣5️⃣ A **triangle-shaped flag** has sides **20 cm, 21 cm, and 29 cm**. Find the **cost of coloring** it at ₹8 per cm².
—
### **📌 Bonus Challenge Questions**
🎯 A **triangular swimming pool** has sides **50 m, 80 m, and 100 m**. The **depth is 2.5 m**. Find the **total water capacity** in liters. (1 m³ = 1000 liters)
🎯 A **triangular plot** has sides **25 m, 39 m, and 50 m**. The government wants to **build a circular park inside** that covers the maximum possible area. Find the **radius of the largest inscribed circle** in the triangle.
—
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February 5, 2025
Past CBSE exam questions on Heron’s Formula
Past CBSE exam questions** on **Heron’s Formula
# **Problem 1: Direct Application of Heron’s Formula**
📌 **CBSE 2018 Question:**
Find the area of a triangle with sides **7 cm, 8 cm, and 9 cm** using Heron’s formula.
#### **Solution:**
**Step 1: Find the Semi-Perimeter (s)**
\[
s = \frac{7+8+9}{2} = \frac{24}{2} = 12 \text{ cm}
\]
**Step 2: Apply Heron’s Formula**
\[
\text{Area} = \sqrt{s(s-a)(s-b)(s-c)}
\]
\[
= \sqrt{12(12-7)(12-8)(12-9)}
\]
**Step 3: Simplify the Expression**
\[
= \sqrt{12 \times 5 \times 4 \times 3}
\]
\[
= \sqrt{720}
\]
\[
= 6\sqrt{20} = 6 \times 4.47 \approx 26.82 \text{ cm}^2
\]
✅ **Final Answer: 26.82 cm²**
—
### **Problem 2: Application in Composite Figures**
📌 **CBSE 2022 Question:**
A quadrilateral is divided into two triangles with sides **5 cm, 6 cm, 7 cm** and **8 cm, 10 cm, 6 cm**. Find its total area using Heron’s formula.
#### **Solution:**
✅ **Step 1: Find the Area of Triangle 1 (5 cm, 6 cm, 7 cm)**
**Semi-perimeter:**
\[
s = \frac{5+6+7}{2} = \frac{18}{2} = 9 \text{ cm}
\]
Apply Heron’s Formula:
\[
\text{Area} = \sqrt{9(9-5)(9-6)(9-7)}
\]
\[
= \sqrt{9 \times 4 \times 3 \times 2}
\]
\[
= \sqrt{216} \approx 14.7 \text{ cm}^2
\]
✅ **Step 2: Find the Area of Triangle 2 (8 cm, 10 cm, 6 cm)**
**Semi-perimeter:**
\[
s = \frac{8+10+6}{2} = \frac{24}{2} = 12 \text{ cm}
\]
**Apply Heron’s Formula:**
\[
\text{Area} = \sqrt{12(12-8)(12-10)(12-6)}
\]
\[
= \sqrt{12 \times 4 \times 2 \times 6}
\]
\[
= \sqrt{576} = 24 \text{ cm}^2
\]
✅ **Final Step: Total Area of Quadrilateral**
\[
= 14.7 + 24 = 38.7 \text{ cm}^2
\]
✅ **Final Answer: 38.7 cm²**
—
### **Problem 3: Real-Life Application-Based Question**
📌 **CBSE 2021 Question:**
A triangular plot has sides **50 m, 72 m, and 78 m**. Find the **cost of fencing** it at ₹12 per meter.
#### **Solution:**
✅ **Step 1: Find the Perimeter**
\[
\text{Perimeter} = 50 + 72 + 78 = 200 \text{ m}
\]
✅ **Step 2: Find the Semi-Perimeter (s)**
\[
s = \frac{200}{2} = 100 \text{ m}
\]
✅ **Step 3: Apply Heron’s Formula**
\[
\text{Area} = \sqrt{100(100-50)(100-72)(100-78)}
\]
\[
= \sqrt{100 \times 50 \times 28 \times 22}
\]
\[
= \sqrt{3080000} \approx 1755.69 \text{ m}^2
\]
✅ **Step 4: Find the Cost of Fencing**
Since fencing is charged at ₹12 per meter:
\[
\text{Cost} = \text{Perimeter} \times 12
\]
\[
= 200 \times 12 = 2400
\]
✅ **Final Answer: ₹2400**
—
### **Key Takeaways for Exams:**
✔ **Direct Application** questions appear in every exam.
✔ **Composite Figures** questions are tested in higher-order thinking problems.
✔ **Real-Life Application Questions** appear every **2-3 years**.
✔ **Show Full Steps in Exams** for full marks.
—
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February 5, 2025
Critical Evaluation of Chapter 12: Heron’s Formula
Critical Evaluation of Chapter 12: Heron’s Formula
### **1. Understanding Heron’s Formula**
Heron’s formula is used to calculate the **area of a triangle** when all three sides are known. The formula is:
\[
\text{Area} = \sqrt{s(s-a)(s-b)(s-c)}
\]
where
\[
s = \frac{a+b+c}{2}
\]
is the **semi-perimeter** of the triangle.
This formula is **particularly useful for triangles where the height is not known** and is also applied to **irregular composite figures**.
—
### **2. Common Challenges Students Face**
❌ **Substitution Errors:** Incorrectly substituting side values in the formula.
❌ **Square Root Calculation Mistakes:** Errors while simplifying the square root expression.
❌ **Misinterpretation of Semi-Perimeter (s):** Forgetting to divide by 2.
❌ **Application to Composite Figures:** Difficulty in breaking complex shapes into triangles.
—
### **3. Evaluation Based on CBSE Past 10 Years’ Exam Papers**
#### **(A) Direct Application of Heron’s Formula**
📌 **Repeated in Almost Every Exam**
**Example Question (CBSE 2015, 2018, 2022):**
Find the area of a triangle with sides **7 cm, 8 cm, and 9 cm** using Heron’s formula.
✅ **Pattern Observed:**
At least one **direct application** question appears in every CBSE exam.
—
#### **(B) Heron’s Formula in Composite Figures**
📌 **Frequently Asked in Higher-Order Thinking Questions (HOTs)**
**Example Question (CBSE 2016, 2019, 2023):**
A quadrilateral is divided into two triangles with sides **5 cm, 6 cm, 7 cm** and **8 cm, 10 cm, 6 cm**. Find its total area using Heron’s formula.
✅ **Pattern Observed:**
CBSE often asks **questions combining multiple triangles** into a single composite shape.
—
#### **(C) Real-Life Application-Based Problems**
📌 **Asked Every 2-3 Years**
**Example Question (CBSE 2014, 2017, 2021):**
A triangular plot has sides **50 m, 72 m, and 78 m**. Find the cost of fencing it at ₹12 per meter.
✅ **Pattern Observed:**
These questions test **conceptual understanding and practical application**.
—
### **4. Strategies to Master This Chapter for CBSE Exams**
✅ **Memorize the Formula Properly** – Most mistakes happen due to incorrect formula usage.
✅ **Practice Square Root Calculations** – Helps in quick and accurate solutions.
✅ **Solve Past Year Questions** – Identifies patterns and frequently asked question types.
✅ **Work on Composite Figures** – Break down irregular shapes into **triangular components**.
—
### **5. Exam Strategy**
📌 **Stepwise Solutions:** CBSE awards marks for proper steps, not just the final answer.
📌 **Double-Check Calculations:** Small arithmetic errors can lead to wrong answers.
📌 **Use Rough Work for Square Root Simplification:** Avoid skipping steps in calculations.
—
CBSE Class 9, Mathematics, Chapter 12, Heron’s Formula, Semi-Perimeter, Triangle Area, Composite Figures, Square Root Calculations, Past Year CBSE Papers, HOTs Questions, Exam Strategy, CBSE 2024, CBSE Previous Year Questions, Geometry, Real-Life Applications.
—
Would you like **step-by-step solved solutions** for past CBSE questions?comments
February 4, 2025
Critical Evaluation of Solve Past Year Papers for Chapter 11 Constructions
Critical Evaluation of Solve Past Year Papers for Chapter 11 Constructions
Solving past year CBSE papers is a crucial strategy for mastering **Chapter 11: Constructions**. It helps students recognize **common question patterns, marking schemes, and required accuracy levels**. Here’s a breakdown of how past paper analysis can improve performance in **Constructions**:
—
### **1. Common Patterns in CBSE Questions (Last 10 Years)**
#### **(A) Repeated Question Types**
– **Basic Geometric Constructions (Angle Bisectors, Perpendicular Bisectors, etc.)**
– **Triangle Construction Based on Different Conditions**
– **Application-Based Construction Problems (e.g., using given perimeter & angles)**
**Example:**
– *2015, 2018, 2022:* Construct an angle of 75° using a compass.
– *2017, 2019, 2023:* Construct a perpendicular bisector for a given line segment.
📌 **Pattern Observed:** *Basic constructions are repeated in almost every exam.*
—
#### **(B) Triangle Construction Variations**
– **Given Base, Base Angle, and Sum of Other Two Sides**
– **Given Base, Base Angle, and Difference of Other Two Sides**
– **Given Perimeter and Base Angles**
**Example:**
– *2014, 2016, 2021:* Construct a triangle where the base is **6 cm**, the base angle is **45°**, and the sum of the other two sides is **10 cm**.
📌 **Pattern Observed:** *At least one triangle construction question is asked every year.*
—
#### **(C) Higher-Order Thinking Questions (HOTs)**
– Some CBSE exams include **application-based construction** where students must apply multiple steps.
– **Example (2020, 2023):** *Construct a right-angled triangle given the hypotenuse and one side.*
📌 **Pattern Observed:** *HOTs-based construction problems appear every 2-3 years.*
—
### **2. Why Solving Past Papers is Beneficial**
✅ **Identifies Frequently Asked Topics** – Ensures focused revision.
✅ **Improves Construction Accuracy** – Builds confidence in using a **compass and ruler correctly**.
✅ **Enhances Time Management** – Helps complete the section **within CBSE time limits**.
✅ **Understands Marking Scheme** – Some questions carry **2-3 marks**, while detailed constructions carry **4 marks**.
—
### **3. Common Mistakes Students Make in CBSE Exams**
❌ **Improper Compass Usage:** Small errors in radius lead to incorrect results.
❌ **Not Labeling Correctly:** Missing points or measurements may result in marks deduction.
❌ **Skipping Justification:** CBSE marking schemes require stepwise explanations.
—
### **4. Exam Strategy for Constructions**
📌 **Practice at Least 5 Past Year Questions Per Week**
📌 **Follow CBSE Blueprint for Marking Scheme**
📌 **Use a Sharp Pencil & High-Quality Compass for Accuracy**
📌 **Label Every Point Clearly (as per CBSE Guidelines)**
Would you like me to generate **step-by-step diagrams** for past year construction problems? plz comments……
February 4, 2025
Chapter 11: Constructions (CBSE Class 9 Mathematics)
Chapter 11: Constructions (CBSE Class 9 Mathematics)
## **1. Key Concepts in Constructions**
Chapter 11 of CBSE Class 9 Mathematics focuses on **geometrical constructions** using a ruler and compass. This chapter is crucial as it builds the foundation for higher-level geometry and practical applications.
### **Topics Covered:**
1. **Basic Constructions**
– Constructing a bisector of a given angle.
– Constructing the perpendicular bisector of a line segment.
2. **Construction of Triangles**
– Given base, base angle, and sum of the other two sides.
– Given base, base angle, and difference of the other two sides.
– Given perimeter and two base angles.
—
## **2. Critical Evaluation of the Chapter**
### **(a) Common Challenges Faced by Students**
1. **Difficulty in Maintaining Precision:**
– Errors in measurements lead to incorrect constructions.
– Slight mistakes in using a compass result in inaccurate figures.
2. **Misinterpretation of Given Data:**
– Confusion between sum/difference of sides in triangle constructions.
– Misplacing the base angle or using the wrong approach.
3. **Errors in Using a Compass and Ruler Together:**
– Students often struggle with drawing perpendicular bisectors accurately.
4. **Forgetting Theoretical Justifications:**
– Many students focus on drawing but fail to justify their steps logically.
—
## **3. Evaluation of Past 10 Years’ CBSE Questions**
### **1. Basic Construction-Based Questions**
#### **Question (2023, 2020, 2017, 2015)**
– Construct an angle of **75°** using a compass and bisector method.
#### **Solution:**
1. Draw a ray \( OA \).
2. Using a compass, mark an arc from \( O \) that cuts \( OA \) at \( B \).
3. Without changing the compass width, place it at \( B \) and draw another arc to get a point \( C \).
4. Keeping the compass at \( C \), mark another arc to get point \( D \).
5. Bisect \( \angle ABC \) to get \( 75^\circ \).
✅ **Final Answer: Angle of 75° Constructed**
—
### **2. Triangle Construction Questions**
#### **Question (2022, 2018, 2014)**
– Construct a **triangle** where the base is **7 cm**, base angle is **50°**, and the sum of the other two sides is **12 cm**.
#### **Solution:**
1. Draw the base \( BC = 7 cm \).
2. Draw \( \angle B = 50^\circ \).
3. Extend the line beyond \( B \).
4. From \( B \), draw an arc of **12 cm** along the extended line.
5. Connect this new point with \( C \).
6. Bisect this line to locate the third vertex.
✅ **Final Answer: Triangle Constructed Successfully**
—
### **3. Construction with Perpendicular Bisectors**
#### **Question (2021, 2019, 2016)**
– Construct a **perpendicular bisector** for a line segment of **8 cm**.
#### **Solution:**
1. Draw a line \( AB = 8 cm \).
2. Using a compass, place it at \( A \) and draw arcs above and below the line.
3. Without changing the radius, repeat the process from \( B \).
4. Mark the intersection points and draw a perpendicular bisector.
✅ **Final Answer: Perpendicular bisector drawn correctly**
—
### **4. Application-Based Questions**
#### **Question (2020, 2015, 2012)**
– Given the perimeter of a **triangle = 15 cm** and base angles **45° and 60°**, construct the triangle.
#### **Solution:**
1. Draw a line segment equal to **15 cm (perimeter)**.
2. Construct **45°** and **60°** at each end.
3. The intersection of these two rays gives the required triangle.
✅ **Final Answer: Triangle Constructed Using Perimeter**
—
## **4. Exam Preparation Tips**
1. **Practice with Precision:** Small errors can affect the accuracy of the construction.
2. **Revise All Triangle Construction Methods:** Understand when to apply each method.
3. **Use Proper Justifications:** Always explain why a step is performed.
4. **Solve Past Year Papers:** This helps in identifying common patterns.
—
Would you like a step-by-step construction diagram for any of these problems? 😊
February 1, 2025
Areas of Parallelograms and Triangles
Areas of Parallelograms and Triangles
To help you visualize better and prepare comprehensively, here are more practice problems along with explanations to strengthen the concepts.
—
### **Problem 1: Prove a Property of a Triangle within a Parallelogram**
#### **Problem Statement**:
Prove that a triangle formed by joining any vertex of a parallelogram to the midpoints of the opposite side has one-fourth the area of the parallelogram.
#### **Solution with Diagram**:
1. **Steps**:
– Draw a parallelogram \( ABCD \).
– Mark the midpoints \( P \) and \( Q \) of sides \( BC \) and \( CD \), respectively.
– Join \( A \) to \( P \) and \( Q \) to form \( \triangle APQ \).
2. **Proof**:
– Since \( P \) and \( Q \) are midpoints, the line segment \( PQ \) is parallel to \( AB \) and half its length.
– The area of \( \triangle APQ \) is proportional to the base \( PQ \) and the height from \( A \) to \( PQ \).
– The height is half the height of the parallelogram because \( PQ \) divides \( ABCD \) into equal halves.
– Hence, \( \text{Area of } \triangle APQ = \frac{1}{4} \times \text{Area of Parallelogram ABCD.} \)
—
### **Problem 2: Calculate the Area of a Quadrilateral Using Triangles**
#### **Problem Statement**:
Find the area of a quadrilateral \( ABCD \) with vertices \( A(2, 3), B(6, 7), C(10, 3), D(6, -1) \).
#### **Solution with Diagram**:
1. **Steps**:
– Divide the quadrilateral \( ABCD \) into two triangles: \( \triangle ABC \) and \( \triangle ACD \).
– Use the formula for the area of a triangle in coordinate geometry:
\[
\text{Area} = \frac{1}{2} \left| x_1(y_2 – y_3) + x_2(y_3 – y_1) + x_3(y_1 – y_2) \right|
\]
2. **Area of \( \triangle ABC \)**:
\[
\text{Vertices: } A(2, 3), B(6, 7), C(10, 3)
\]
Substitute into the formula:
\[
\text{Area} = \frac{1}{2} \left| 2(7-3) + 6(3-3) + 10(3-7) \right|
\]
\[
= \frac{1}{2} \left| 2(4) + 6(0) + 10(-4) \right|
\]
\[
= \frac{1}{2} \left| 8 – 40 \right| = \frac{1}{2} \times 32 = 16 \, \text{sq. units.}
\]
3. **Area of \( \triangle ACD \)**:
\[
\text{Vertices: } A(2, 3), C(10, 3), D(6, -1)
\]
Substitute into the formula:
\[
\text{Area} = \frac{1}{2} \left| 2(3 – (-1)) + 10(-1 – 3) + 6(3 – 3) \right|
\]
\[
= \frac{1}{2} \left| 2(4) + 10(-4) + 6(0) \right|
\]
\[
= \frac{1}{2} \left| 8 – 40 \right| = \frac{1}{2} \times 32 = 16 \, \text{sq. units.}
\]
4. **Total Area of Quadrilateral**:
\[
\text{Area of } ABCD = \text{Area of } \triangle ABC + \text{Area of } \triangle ACD = 16 + 16 = 32 \, \text{sq. units.}
\]
—
### **Problem 3: Relationship Between Parallelogram and Triangle Areas**
#### **Problem Statement**:
In a parallelogram \( ABCD \), diagonal \( AC \) divides it into two triangles. Prove that the area of \( \triangle ABC \) is equal to the area of \( \triangle ADC \).
#### **Solution**:
1. **Steps**:
– The diagonal \( AC \) divides the parallelogram \( ABCD \) into \( \triangle ABC \) and \( \triangle ADC \).
– Both triangles share the same diagonal \( AC \) as the base.
– Since \( AC \) is a diagonal, it divides the parallelogram into two equal parts.
– The height of both triangles is the perpendicular distance between \( AC \) and the opposite vertices.
2. **Conclusion**:
The areas of \( \triangle ABC \) and \( \triangle ADC \) are equal because they share the same base and height.
—
### **Problem 4: Mixed Concept Problem with Coordinates**
#### **Problem Statement**:
Prove that the midpoints of the sides of a triangle form a parallelogram, and find its area using coordinate geometry if the vertices of the triangle are \( A(0, 0), B(4, 6), C(8, 0) \).
#### **Solution**:
1. **Steps**:
– Find the midpoints of sides \( AB \), \( BC \), and \( AC \):
\( M_1 \): Midpoint of \( AB = \left( \frac{0+4}{2}, \frac{0+6}{2} \right) = (2, 3) \).
\( M_2 \): Midpoint of \( BC = \left( \frac{4+8}{2}, \frac{6+0}{2} \right) = (6, 3) \).
\( M_3 \): Midpoint of \( AC = \left( \frac{0+8}{2}, \frac{0+0}{2} \right) = (4, 0) \).
– Prove that \( M_1M_2M_3M_4 \) is a parallelogram by verifying that opposite sides are parallel and equal.
– Use the area formula for coordinate geometry to find the area of the parallelogram.
—
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January 28, 2025
Detailed Solutions for Chapter 9 Practice Problems
Detailed Solutions for Chapter 9 Practice Problems
1. Prove that if two triangles are on the same base and between the same parallels, they have equal areas.**
Given
– Two triangles \( \triangle ABC \) and \( \triangle DBC \) share the same base \( BC \).
– Both triangles lie between the same parallels \( BC \) and \( AD \).
**To Prove**:
\[
\text{Area of } \triangle ABC = \text{Area of } \triangle DBC
\]
**Proof**:
1. Draw a perpendicular from \( A \) to \( BC \), meeting \( BC \) at \( P \). Let the height be \( h_1 \).
2. Similarly, draw a perpendicular from \( D \) to \( BC \), meeting \( BC \) at \( Q \). Let the height be \( h_2 \).
3. Since both \( A \) and \( D \) lie on the same parallel \( AD \), we know \( h_1 = h_2 \).
The area of \( \triangle ABC \):
\[
\text{Area} = \frac{1}{2} \times \text{Base} \times \text{Height} = \frac{1}{2} \times BC \times h_1
\]
The area of \( \triangle DBC \):
\[
\text{Area} = \frac{1}{2} \times \text{Base} \times \text{Height} = \frac{1}{2} \times BC \times h_2
\]
Since \( h_1 = h_2 \):
\[
\text{Area of } \triangle ABC = \text{Area of } \triangle DBC
\]
**Conclusion**:
Triangles on the same base and between the same parallels have equal areas.
—
**2. A parallelogram has sides \( 12 \, \text{cm} \) and \( 15 \, \text{cm} \). Its height corresponding to the base \( 12 \, \text{cm} \) is \( 8 \, \text{cm} \). Find its area.**
**Solution**:
– **Base** \( = 12 \, \text{cm} \)
– **Height** \( = 8 \, \text{cm} \)
Area of a parallelogram:
\[
\text{Area} = \text{Base} \times \text{Height}
\]
Substitute the values:
\[
\text{Area} = 12 \times 8 = 96 \, \text{cm}^2
\]
#### **Answer**:
The area of the parallelogram is \( 96 \, \text{cm}^2 \).
—
**3. The vertices of a triangle are \( A(-2, -3), B(3, 5), \text{and } C(5, -1) \). Calculate its area using coordinate geometry.**
**Solution**:
The formula for the area of a triangle with vertices \( (x_1, y_1), (x_2, y_2), (x_3, y_3) \) is:
\[
\text{Area} = \frac{1}{2} \left| x_1(y_2 – y_3) + x_2(y_3 – y_1) + x_3(y_1 – y_2) \right|
\]
Substitute \( A(-2, -3), B(3, 5), C(5, -1) \):
\[
\text{Area} = \frac{1}{2} \left| -2(5 – (-1)) + 3(-1 – (-3)) + 5((-3) – 5) \right|
\]
\[
= \frac{1}{2} \left| -2(6) + 3(2) + 5(-8) \right|
\]
\[
= \frac{1}{2} \left| -12 + 6 – 40 \right|
\]
\[
= \frac{1}{2} \left| -46 \right|
\]
\[
= \frac{1}{2} \times 46 = 23 \, \text{sq. units}
\]
#### **Answer**:
The area of the triangle is \( 23 \, \text{sq. units} \).
—
### **4. A quadrilateral \( ABCD \) is divided into two triangles by a diagonal. Prove that the sum of their areas equals the area of the quadrilateral.**
#### **Given**:
Quadrilateral \( ABCD \) with diagonal \( AC \) dividing it into \( \triangle ABC \) and \( \triangle ACD \).
#### **To Prove**:
\[
\text{Area of } \triangle ABC + \text{Area of } \triangle ACD = \text{Area of Quadrilateral } ABCD
\]
#### **Proof**:
1. Draw diagonal \( AC \).
2. The area of \( \triangle ABC \) is given by:
\[
\text{Area} = \frac{1}{2} \times \text{Base} \times \text{Height}
\]
3. The area of \( \triangle ACD \) is similarly calculated using \( AC \) as the base.
Adding the areas of the two triangles:
\[
\text{Area of } \triangle ABC + \text{Area of } \triangle ACD = \text{Area of Quadrilateral } ABCD
\]
#### **Conclusion**:
The total area of the two triangles equals the area of the quadrilateral.
—
### **5. Prove that the diagonals of a parallelogram divide it into four triangles of equal areas.**
#### **Given**:
A parallelogram \( ABCD \) with diagonals \( AC \) and \( BD \) intersecting at \( O \).
#### **To Prove**:
\[
\text{Area of } \triangle AOB = \text{Area of } \triangle BOC = \text{Area of } \triangle COD = \text{Area of } \triangle DOA
\]
#### **Proof**:
1. In \( \triangle AOB \) and \( \triangle COD \):
– \( AC \) is the diagonal, and it divides the parallelogram into two equal parts.
– Therefore, \( \text{Area of } \triangle AOB = \text{Area of } \triangle COD. \)
2. Similarly, in \( \triangle BOC \) and \( \triangle DOA \):
– \( BD \) divides the parallelogram into two equal parts.
– Therefore, \( \text{Area of } \triangle BOC = \text{Area of } \triangle DOA. \)
3. Since \( AC \) and \( BD \) intersect at \( O \), the four triangles are of equal area.
#### **Conclusion**:
The diagonals of a parallelogram divide it into four triangles of equal areas.
—
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January 28, 2025