Numerical Example - 1.2.1.2.3 | Module 1: Biology – The Engineering of Life | Biology (Biology for Engineers)
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1.2.1.2.3 - Numerical Example

Practice

Interactive Audio Lesson

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Camera Lens Calculation

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0:00
Teacher
Teacher

Today, we're going to learn how to calculate the necessary aspects of a camera lens using a numerical example. Let's start with the thin lens formula: 1/f = 1/do + 1/di.

Student 1
Student 1

What do f, do, and di represent in that formula?

Teacher
Teacher

Great question! 'f' is the focal length, 'do' is the object distance, and 'di' is the image distance. Essentially, we want to find the image distance. If we know the focal length and object distance, we can find di.

Student 2
Student 2

Can you give us an example?

Teacher
Teacher

Sure! Let’s say the focal length (f) is 50 mm and the object distance (do) is 2000 mm. We can rearrange the formula: 1/di = 1/f - 1/do.

Student 3
Student 3

So what do we get when we plug those values in?

Teacher
Teacher

Let’s calculate: 1/di = 1/50 - 1/2000, simplifying we find 1/di = 39/2000 which means di is approximately 51.28 mm. This distance tells us where the image will be formed relative to the lens.

Student 4
Student 4

That’s really cool! So we’re using math to simulate how the eye works?

Teacher
Teacher

Exactly! By understanding these calculations, we mimic biological systems. To recap, remember 'f' is focal length, 'do' is object distance, and 'di' is image distance. This is a clear example of the intersection between biology and engineering.

Lift Calculation for Aircraft

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Teacher
Teacher

Next, let's explore how aircraft generate lift. We can use a simplified lift equation: L = (1/2) * ρ * v² * A * CL.

Student 1
Student 1

What do the letters stand for in the lift equation?

Teacher
Teacher

Great question! Here, 'L' is lift, 'ρ' is air density, 'v' is airspeed, 'A' is wing area, and 'CL' is the lift coefficient.

Student 2
Student 2

How do we use this in an example?

Teacher
Teacher

Let’s say we have an aircraft wing with an area of 100 m², flying at 200 m/s, with air density of 0.5 kg/m³ and a lift coefficient of 0.8. Plugging in these numbers: L = (1/2) * 0.5 * (200)² * 100 * 0.8.

Student 3
Student 3

What result do we get?

Teacher
Teacher

Calculating that gives us L = 800,000 Newtons! This amount of lift must be equal to or greater than the weight of the aircraft for it to maintain flight.

Student 4
Student 4

So we can calculate real-world applications with these concepts?

Teacher
Teacher

Absolutely! This demonstrates how we can harness biological inspiration in engineering design. Always remember the lift equation, as it’s essential for understanding aircraft dynamics.

Introduction & Overview

Read a summary of the section's main ideas. Choose from Basic, Medium, or Detailed.

Quick Overview

This section illustrates numerical applications of concepts discussed in biology and engineering, using examples of camera design and aircraft lift.

Standard

In this section, numerical examples are provided to demonstrate the application of biological principles in engineering contexts, particularly focusing on camera lens calculations and aircraft lift equations. These examples emphasize the intersection of biology and engineering through mathematical modeling.

Detailed

In this section, we explore numerical examples that highlight the relationship between biology and engineering, focusing specifically on the design and functionality of systems inspired by biological organisms. One example illustrates how a camera lens's focal length can be calculated using the formula for thin lenses, showcasing the application of engineering principles to replicate biological functions like vision. Additionally, an example is provided for calculating the lift generated by an aircraft wing, applying the lift equation to derive necessary values for successful flight. These calculations exemplify how understanding biological systems can inform engineering designs, illustrating the integration of scientific inquiry and engineering application.

Audio Book

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Camera Focal Length Calculation

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If a camera lens has a focal length (f) of 50 mm, and an object is 2000 mm (do) away, the image will be formed at a distance (di) from the lens calculated as:

1/50 = 1/2000 + 1/di

1/di = 1/50 − 1/2000 = (40 − 1)/2000 = 39/2000

di = 2000/39 ≈ 51.28 mm.

Detailed Explanation

In this chunk, we are calculating where the image will be formed in relation to the lens based on the distance of the object and the lens's focal length. The lens's focal length (f) is the distance at which it focuses light effectively. Here, the focal length is given as 50 mm, and the object is 2000 mm away from the lens.

Using the lens formula, we rearranged the formula to find the image distance (di). We start with the lens formula:

1/f = 1/do + 1/di,

where do is the object distance and di is the image distance. Substituting the known values, we can solve for di. After doing the math, we find that the image will be formed approximately 51.28 mm from the lens.

This calculation helps understand where to place the image sensor in the camera to capture the photograph.

Examples & Analogies

Think of it as trying to shine a flashlight on a wall. The flashlight has a certain angle (like the lens has a focal length), and how far you hold the flashlight from the wall affects how focused the light beam is on the wall. If you hold it too far or too close, the spot might be fuzzy or out of focus. Just like the image from the camera, where light has to come to a point on the sensor to create a clear picture.

Understanding the Lens Formula

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1/f = 1/do + 1/di
where f is the focal length, do is the object distance, and di is the image distance.

Detailed Explanation

This is the fundamental lens formula that relates the focal length (f) of a lens to the distance of the object (do) and the distance of the image (di) produced by the lens. The focal length is a critical measurement because it influences the lens's ability to focus light.

When light passes through a lens, it refracts, or bends, based on the curvature of the lens. The formula helps us understand how far away an object needs to be and how that affects the position of the resulting image. A shorter focal length means a wider field of view, while a longer focal length means a narrower view but with the ability to zoom in on distant objects.

Examples & Analogies

Imagine using a magnifying glass. When you hold it at the right distance from a small object, it appears much larger. If you move it too close or too far away, it goes out of focus. The relationship between the object distance and the focal length determines how clear the enlarged image is, similar to how the lens formula works with cameras.

Definitions & Key Concepts

Learn essential terms and foundational ideas that form the basis of the topic.

Key Concepts

  • Camera Focal Length: The focal length determines where images are created from light passing through the lens.

  • Lift in Aircraft: The lift generated must be sufficient to counteract the weight of the aircraft for flight.

Examples & Real-Life Applications

See how the concepts apply in real-world scenarios to understand their practical implications.

Examples

  • Calculating the zoom effect of a camera lens based on its focal length.

  • Estimating the lift produced by an aircraft based on wing area and speed.

Memory Aids

Use mnemonics, acronyms, or visual cues to help remember key information more easily.

🎵 Rhymes Time

  • Focal length, distance you seek, light converges, so to speak.

📖 Fascinating Stories

  • Imagine a magical camera that captures the world perfectly, just like the eye does, connecting the biology of sight with the engineering of vision.

🧠 Other Memory Gems

  • To calculate lift: L = 1/2ρv²A*CL - remember 'Loves Weights And Coefficients'.

🎯 Super Acronyms

FDO - Focal length, Distance of object, Distance of image.

Flash Cards

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Glossary of Terms

Review the Definitions for terms.

  • Term: Focal Length (f)

    Definition:

    The distance from the lens to the image point where light converges.

  • Term: Object Distance (do)

    Definition:

    The distance from the lens to the object being viewed.

  • Term: Image Distance (di)

    Definition:

    The distance from the lens to the formed image.

  • Term: Lift (L)

    Definition:

    The upward force generated by an aircraft's wings that counteracts weight.

  • Term: Lift Coefficient (CL)

    Definition:

    A dimensionless number that relates to the lift characteristics of a wing shape.

  • Term: Air Density (ρ)

    Definition:

    The mass per unit volume of air, affecting lift generation.

  • Term: Airspeed (v)

    Definition:

    The speed at which an aircraft moves relative to the surrounding air.

  • Term: Wing Area (A)

    Definition:

    The surface area of an aircraft's wing, contributing to lift generation.