Chapter 8.2

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This lesson contains 17 slides, with text slides.

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Chapter 8.2

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Period 2

Sound

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This lesson

Recap
Paragraph 8.2 — pitch and frequency
Working independently

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How is sound produced?

Through a vibration

What is sound made off?

Sound waves

How does sound travel over distance?

Through a medium

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Pitch is a word we use to describe how high or low a sound is. For example:

– A whistle has a high pitch.

– A drum has a low pitch.

The pitch of the sound depends on in a string instrument:

1.Thickness: the thinner the string, the higher the pitch

the thicker the string, the lower the pitch

2.Length: the shorter the string, the higher the pitch

3.Tension: the tighter the string, the higher the pitch"

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We can make sound visible. We do this with an oscilloscope.

With the oscilloscope you can analyze the sound.

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The screen of the oscilloscope is divided into small squares. The time base tells you how much time one square represents.

For example: A time base of 500 ms/division means that one square shows 500 milliseconds."

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The vibration period and frequency

Each square on the oscilloscope gives an amount of time called

Time base

time base = 0,5 ms per

division

And each vibration takes a certain

amount of time to complete

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The vibration period and frequency

The vibration period is the amount of time it takes to complete 1 full vibration

In this picture we see multiple vibrations, at which point(s) do we see a completed vibration?

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The vibration period and frequency

With the time 1 square takes up, and the amount of completed vibrations we can calculte the vibration period (T)

For example, we have

3 completed vibrations

What is the time for these 3 vibrations?

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The vibration period and frequency

We divide the time it takes to complete a certain amount of vibrations with the number of vibrations and we get the vibration period (T)

T = 2,4/3=0,8ms = 0,0008 s

So one full vibration = 0,0008 s

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The vibration period and frequency

If we know the period of a vibration we can calculate its frequency (f) in Hertz (Hz)

We can use this the formula

f = 1/T

If we know the frequency and want to

Calculate vibration period: then you can

Use T= 1/f

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The vibration period and frequency

When we calculated T we got the answer of 0,8ms

Now we can calculate the frequency

f = 1/t

f=1/0,0008=1250Hz

Which means 1250 vibrations per second

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The vibration period and frequency

We humans are able to hear sounds with low and high frequencies

Our hearing range is between 20hz and 20000hz

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See the images below. total time is 8 milliseconds go by.

What is the frequency of this wave? use the formula

f = \frac{​ 1 ​ ​}{​ T ​}

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See the images below. you have 1 ms/div.

What is the frequency of this wave? use the formula

f = \frac{​ 1 ​ ​}{​ T ​}

Given

T = 2 milliseconds = 0.002 seconds.

Asked

What is the frequency?

Formula

Calculation

f = 1/T = 1/0.002 =500 Hz

f = \frac{​ 1 ​ ​}{​ T ​}

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Chapter 8.2

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