Sound in our world – Elenco Snap Circuits® Deluxe Sound & Light Combo User Manual

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Sound in Our World

Some of a sound wave’s energy can reflect off

walls or objects and come back to you.

Normally you don’t notice these reflections

when you are speaking because not all of the

energy is reflected, and the delay is so short

that your ears can’t distinguish it from the

original sound, but sometimes (such as in a

very large open room) you can hear them -

these are echoes! You hear an echo when a

lot of the energy of your voice is reflected back

to you after a noticeable delay. The delay time

is the distance (to the reflection point and

back) divided by the speed of sound. Most

people cannot distinguish reflected sound

waves with delays of less than 1/15 of a

second, and perceive them as being part of

the original sound. Echoes can be simulated

electronically by replaying a recorded sound

with a small delay and at reduced volume. See

project 10 and others for examples.

In project 195, if your speaker is too close to

your microphone then the echo sound can be

picked up by the microphone and echoed

again and again until you can’t hear anything

else. The same thing can occur in telephone

systems, and these systems sometimes have

echo-cancelling circuitry to prevent problems

(especially in overseas calls, where the

transmission delay times may be longer).

Engineers developing sensitive audio

equipment need to make very accurate sound

measurements. They need rooms that are

sealed from outside sounds, and need to

minimize the measured signal’s reflections off

the walls/ceiling/floor. Specialized rooms have

been designed for this, called anechoic

chambers. These chambers are virtually

soundproof and have specially shaped

materials (usually made of foam) on the walls

to absorb sound waves without producing any

echoes. These chambers simulate a quiet,

open space, allowing the engineers to

accurately measure the equipment being

tested.

Everything has a natural frequency, its

resonance frequency, at which it will vibrate

more easily. When sound waves strike an

object at its natural frequency, the object can

absorb and store significantly more energy

from the sound waves, as vibration. To help

understand this concept, think of a playground

swing, which tends to always swing back and

forth at the same rate. If you push the swing at

the ideal moment, it will absorb energy from

you and swing higher. You don’t need to push

the swing very hard to make it go high, you just

need to keep adding energy at the right

moment. In project 198 (Sound Energy

Demonstration), the frequency is tuned to the

speaker’s natural frequency, making it vibrate

noticeably.

Resonance is an important consideration in

the design of musical instruments, and also in

construction. If high winds blow on a tall

building or a bridge at the structure’s resonant

frequency, vibrations can slowly increase until

the structure is torn apart and collapses.
A cone can help you project your voice. A cone

keeps the sound waves (air pressure variations)

together longer, so they don’t spread out so

quickly. Long ago, people who had trouble

hearing used an ear trumpet, which helps

collect sound waves. A person would speak into

the wide end of the ear trumpet, and the trumpet

makes the sound louder at the listening person’s

ear. Electronic hearing aids have replaced ear

trumpets. Doctors use a stethoscope to hear

inside patient’s bodies. A stethoscope uses a

cone-like structure to collect sound waves; then

passes them into the doctor’s ear.

Sound waves reflecting off a wall

Anechoic chamber

Small pushes at the right

moment will make the swing

go higher.

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