10.1.3 - Verification of areas using Heron’s formula
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Introduction to Heron's Formula
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Today, we are going to explore Heron's formula. Can anyone already tell me what this formula helps us find?
The area of a triangle?
That's correct! It allows us to calculate the area, even when we only know the lengths of the sides. Let's define it. Heron's formula states that the area of a triangle can be calculated from its sides a, b, and c by first calculating the semi-perimeter s, which is \(s = \frac{a + b + c}{2}\).
What do we do with 's' after we find it?
Once we have 's', we can plug it into the formula: \(\text{Area} = \sqrt{s(s-a)(s-b)(s-c)}\). Each part of that expression uses a side length!
Can you give us an example?
Absolutely! Let's consider a triangle with sides 40 meters, 32 meters, and 24 meters. First, we find \(s\) which equals 48 meters, then we check how Heron's formula gives us the area.
Calculating Area with Examples
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Using our triangle with sides 40m, 32m, and 24m, let's calculate the area together. First, recapping, what is \(s\)?
The semi-perimeter would be 48m.
Correct! So now let’s plug these into Heron's formula. What do we get?
We get \(\sqrt{48(48-40)(48-32)(48-24)}\).
Exactly! Now simplify that expression to find the area.
It simplifies to 384 square meters!
Right! And how can we visualize this in comparison to using the base-height method?
The area is the same! We can check by calculating it with '1/2 × base × height'!
Great observation! This illustrates the effectiveness of Heron’s formula.
Application in Different Triangle Types
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Now, let's apply Heron's formula on different triangle types. How about an equilateral triangle with each side measuring 10 cm?
For this triangle, we'd find \(s = 15\) cm first!
Good work! Now can you calculate the area from there?
Sure! The area would be \(\sqrt{15(15-10)(15-10)(15-10)} = 25\sqrt{3}\) cm².
Excellent. Now what about an isosceles triangle with sides 5 cm and 8 cm, having unequal sides of a and b?
The semi-perimeter \(s\) would be 9 cm, and I can calculate the area there as well!
Perfect! Everyone is applying Heron's formula wonderfully.
Verification and Cross-Checking
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Finally, verification is key. When verifying Heron's formula, what can we contrast it with?
We could check the area using basic geometry methods!
Exactly! By comparing Heron’s area to that calculated using base and height, we ensure our computations are correct. Shall we practice another?
Yes! Let's do a triangle with sides summing to a perimeter of 32 cm.
Great teamwork everyone, keep practicing applying Heron's formula!
Introduction & Overview
Read summaries of the section's main ideas at different levels of detail.
Quick Overview
Standard
This section introduces Heron's formula for finding the area of a triangle using the lengths of its sides. It illustrates how to apply the formula through various triangle examples, emphasizing verification of computed areas.
Detailed
Verification of Areas Using Heron’s Formula
In this section, we explore the application of Heron’s formula, which enables the calculation of the area of a triangle given the lengths of its sides. The formula states that
\[
\text{Area} = \sqrt{s(s-a)(s-b)(s-c)}
\]
where \(s\) is the semi-perimeter defined as \(s = \frac{a + b + c}{2}\), with \(a\), \(b\), and \(c\) representing the sides of the triangle.
We begin with an example triangle park with sides measuring 40m, 32m, and 24m. Calculating the semi-perimeter gives \(s = 48m\) and using Heron's formula, we find the area matches our verification through the traditional base-height method, showcasing the consistency and effectiveness of the formula. We then apply Heron’s formula to additional triangles, examining an equilateral triangle with a side of 10 cm, and an isosceles triangle with sides measuring 5 cm and 8 cm, thus verifying versatility in various triangle types.
This section reinforces the significance of Heron’s formula in practical applications where traditional height-based area calculations may not be feasible.
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Understanding Heron’s Formula
Chapter 1 of 4
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Chapter Content
The formula given by Heron about the area of a triangle, is also known as Hero’s formula. It is stated as:
Area of a triangle = \( \sqrt{s \cdot (s - a) \cdot (s - b) \cdot (s - c)} \)
where a, b and c are the sides of the triangle, and s = semi-perimeter, i.e., half the perimeter of the triangle = \( \frac{a + b + c}{2} \).
Detailed Explanation
Heron’s formula allows us to find the area of a triangle when the lengths of all three sides are known, without needing to calculate the height. To apply this formula, you first calculate the semi-perimeter (s), which is half of the triangle's perimeter. Then you substitute the values of a, b, and c (the sides) along with s into the formula to find the area.
Examples & Analogies
Imagine you have a triangular garden divided into three sections with sides measuring 40 m, 32 m, and 24 m. You can find the area of this garden without having to measure how high it is by using Heron’s formula.
Calculating Area of a Triangular Park
Chapter 2 of 4
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Chapter Content
Let us apply it to calculate the area of the triangular park ABC, mentioned above (see Fig. 10.2).
Let us take a = 40 m, b = 24 m, c = 32 m,
so that we have s = \( \frac{40 + 24 + 32}{2} = 48 \ m.\)
s – a = (48 – 40) m = 8 m,
s – b = (48 – 24) m = 24 m,
s – c = (48 – 32) m = 16 m.
Therefore, area of the park ABC = \( \sqrt{s \cdot (s - a) \cdot (s - b) \cdot (s - c)} \ = \sqrt{48 \cdot 8 \cdot 24 \cdot 16} = 384 \ m^2. \)
Detailed Explanation
In this example, we start by defining the sides of the triangle. By calculating the semi-perimeter using the formula \( s = \frac{a + b + c}{2} \), we find that the semi-perimeter is 48 m. We then find the values for \( s - a \), \( s - b \), and \( s - c \). Substituting these values back into Heron’s formula gives us the area of the triangular park as 384 m².
Examples & Analogies
Think of the triangular park like slicing a piece of pizza into three distinct slices. Each slice represents a side of the triangle. By knowing the lengths of the slices (sides), you can find out the entire area of the pizza using Heron’s formula without needing to measure how tall the pizza is at a point.
Verification with Right Triangle Properties
Chapter 3 of 4
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Chapter Content
We see that 32² + 24² = 1024 + 576 = 1600 = 40². Therefore, the sides of the park make a right triangle. The largest side, i.e., BC which is 40 m will be the hypotenuse and the angle between the sides AB and AC will be 90°.
We can check that the area of the park is \( \frac{1}{2} \times 32 \times 24 \ m^2 = 384 m^2. \) We find that the area we have got is the same as we found by using Heron’s formula.
Detailed Explanation
Here we confirm that the triangle formed by the sides of the park is a right triangle because the Pythagorean theorem holds true (the square of the longest side equals the sum of the squares of the other two sides). Additionally, we verify the area calculated using basic geometry (1/2 * base * height) matches the area calculated using Heron’s formula, illustrating its accuracy.
Examples & Analogies
Imagine a garden with a right triangle shape, where the base and height are the flower beds. By figuring out the area from both the height formula and Heron’s formula, you can cross-check your calculations to make sure you have enough soil to fill both beds correctly.
Example Applications of Heron’s Formula
Chapter 4 of 4
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Chapter Content
Now using Heron’s formula, you verify this fact by finding the areas of other triangles discussed earlier viz.,
(i) equilateral triangle with side 10 cm.
(ii) isosceles triangle with unequal side as 8 cm and each equal side as 5 cm.
You will see that...
For (i), we have s = \( \frac{10 + 10 + 10}{2} = 15 \ cm. \)
Area of triangle = \( \sqrt{15 \cdot (15 - 10) \cdot (15 - 10) \cdot (15 - 10)} = 25 \sqrt{3} \ cm². \)
For (ii), we have s = \( \frac{8 + 5 + 5}{2} = 9 \ cm. \)
Area of triangle = \( \sqrt{9 \cdot (9 - 8) \cdot (9 - 5) \cdot (9 - 5)} = 12 \ cm².
Detailed Explanation
In this section, we apply Heron’s formula to different types of triangles. For the equilateral triangle, we find the semi-perimeter and use the formula to calculate the area. For the isosceles triangle, we follow the same process, showing how versatile Heron’s formula is for different shapes of triangles.
Examples & Analogies
Consider building structures like shelters or gazebos, which can be triangular in shape. Knowing how to calculate their area using Heron’s formula can help in calculating materials and costs more efficiently, ensuring you purchase the right amount for each triangular section.
Key Concepts
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Heron's Formula: A method to calculate the area of a triangle using its side lengths.
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Semi-perimeter: The half of the perimeter of a triangle, critical for using Heron's formula.
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Right Triangle: A triangle in which one angle is exactly 90 degrees.
Examples & Applications
{'example': 'Find the area of a triangle with sides 40m, 32m, and 24m.', 'solution': '\[ s = \frac{40 + 32 + 24}{2} = 48m \] \n\[ \text{Area} = \sqrt{s(s-a)(s-b)(s-c)} = \sqrt{48\cdot(48-40)(48-32)(48-24)} = \sqrt{48\cdot8\cdot16\cdot24} = 384 m^2 \]'}
{'example': 'Calculate the area of an equilateral triangle with side 10cm.', 'solution': '\[ s = \frac{10 + 10 + 10}{2} = 15cm \] \n\[ \text{Area} = \sqrt{15\cdot(15-10)(15-10)(15-10)} = \sqrt{15\cdot5\cdot5\cdot5} = 25\sqrt{3} cm^2 \]'}
{'example': 'Area of an isosceles triangle with side lengths 5cm, 5cm, and 8cm.', 'solution': '\[ s = \frac{5 + 5 + 8}{2} = 9cm \] \n\[ \text{Area} = \sqrt{9\cdot(9-5)(9-5)(9-8)} = \sqrt{9\cdot4\cdot4\cdot1} = 12 cm^2 \]'}
Memory Aids
Interactive tools to help you remember key concepts
Rhymes
Heron’s way to find the space, use the sides to set the pace.
Stories
Imagine a triangle trying to find a way to show off its area by revealing the secrets of its sides to calculate the space inside.
Memory Tools
Remember the formula: Sway! Area = √(s(s-a)(s-b)(s-c))!
Acronyms
HAVE
Heights aren't vital
all sides equal.
Flash Cards
Glossary
- Heron's Formula
A formula that gives the area of a triangle when the lengths of all three sides are known.
- Semiperimeter
Half of the perimeter of a triangle, calculated as s = (a + b + c) / 2.
- Area
The amount of space inside a two-dimensional shape, measured in square units.
Reference links
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