Vibrations and Waves: Energy and Motion

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  • 0:05 Vibrations
  • 1:54 Waves
  • 3:28 Amplitude and Energy
  • 5:44 Lesson Summary
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Lesson Transcript
Instructor: April Koch

April teaches high school science and holds a master's degree in education.

What is a wave? What causes waves, and how do they travel from one place to another? This lesson will guide you through the basics of waves. We'll discuss their origins from vibrations and investigate how they carry energy through a medium.


Have you ever been to a party where the music is so loud, you can feel it? I don't mean just the beat in your mind. Sometimes you can literally feel the vibrations of the music in the floor or other objects. People often like to blast their music from their cars on the highway, causing unpleasant buzzing in the vehicles nearby. But, how do we get sensations like these from music playing so far away? How can music travel from somebody's speakers and cause such powerful vibrations in other objects?

To answer this question, let's explore what we mean when we say the word vibration. What are vibrations? Where do we find them? In a guitar string? On a trampoline? What about a cymbal in a drum set? The ground in an earthquake? These are all examples of things that experience vibrations. In each case, there is an object beginning at a resting position, such as the cymbal on its stand, or the string on the guitar. The motion made by the object is in a back-and-forth nature over the resting position. Vibrations are oscillating motions around a fixed position.

When an object vibrates, it exhibits a motion that repeats itself over the same path in a periodic fashion. That is, the time it takes to complete one cycle of the vibration is always the same. Take a look at this system here. We have a mass being suspended from a spring. When the system is at rest, the mass just sits there in the air, stretching the spring to a certain extent because of its weight. But, if someone pulls the mass down a little and lets go, the mass springs upward, past its resting position, and then oscillates up and down at a certain frequency. If we plot its position over the course of time, we see that there is a very regular, periodic nature to its movement. This nature is best represented in the form of a wave.

The mass on a spring creates a wave as it oscillates
An Oscillating Wave


A wave is a disturbance that travels through a medium from one place to another. Waves are formed by the vibration of the object or substance that carries the wave. You can make your own waves in a jump rope by creating a vibration at one end. Begin with the jump rope in its resting position, then move one end quickly up and down. You'll create a wave that travels through the rope from one end to the other. If you do it right, the wave might even bounce off the other end and travel back to your hand.

All waves are caused by some type of vibration. Vibrations cause a disturbance in the medium that becomes the source of the wave. Think about water waves formed when you throw a rock into a pond. The rock hitting the surface causes the water to vibrate. This vibration disturbs the surrounding water, creating waves that move outward from the point of the rock's impact.

If we look more closely at a typical wave, we can see the periodic nature in the shape of the wave itself. Let's plot the wave as a function of time. We'll put seconds along the horizontal axis, and the vertical axis will measure the wave's vertical displacement. Just so we can talk about the wave more clearly, we'll label it with letters at different points. The letters A and E show the low points of the wave, which we call troughs. The letters C and G show the crests of the wave. A full wave cycle is defined as that portion of the wave between two successive crests, or between two troughs. By looking at how the crests and troughs line up with our horizontal axis, we can see that a full wave cycle always takes the same amount of time. That's why we say that waves have a periodic nature.

Vibration waves are made up of crests and troughs.
Vibration Wave Parts

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