L 22 – Vibrations and Waves [2]  resonance  clocks – pendulum  springs  harmonic motion  mechanical waves  sound waves  musical instruments.

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L 22 – Vibrations and Waves [2]  resonance  clocks – pendulum  springs  harmonic motion  mechanical waves  sound waves  musical instruments

VIBRATING SYSTEMS  Mass and spring on air track  Mass hanging on spring  Pendulum  Torsional oscillator All vibrating systems have one thing in common  restoring force

springs  amazing devices! the harder I pull on a spring, the harder it pulls back the harder I push on a spring, the harder it pushes back stretching compression

Springs obey Hooke’s Law spring force (N) amount of stretching or compressing in meters the strength of a spring is measured by how much force it provides for a given amount of stretch we call this quantity k, the spring constant in N/m magnitude of spring force = k  amount of stretch elastic limit of the spring

simple harmonic oscillator mass m and spring on a frictionless surface 0 A Equilibrium position k k is the spring constant, which measures the stiffness of the spring in Newtons per meter frictionless surface spring that can be stretched or compressed A

Some terminology the maximum displacement of an object from equilibrium is called the AMPLITUDE A the time that it takes to complete one full cycle (A  B  C  B  A ) is called the PERIOD T of the motion if we count the number of full cycles the oscillator completes in a given time, that is called the FREQUENCY f of the oscillator frequency f = 1 / period = 1 / T

follow the mass – position vs. time position time + A - A T T T -A 0 +A

Period of the mass-spring system If the mass is quadrupled, the period is doubled Period of a pendulum of length L Does NOT depend on the mass

Energy in the simple harmonic oscillator a compressed or stretched spring has elastic potential energy this elastic potential energy is what drives the system if you pull the mass from equilibrium and let go, this elastic PE changes into kinetic energy. when the mass passes the equilibrium point, the KE goes back into PE if there is no friction the energy keeps sloshing back and forth but it never decreases

simple harmonic oscillator the period of oscillation is longer (takes more time to complete a cycle) if a bigger mass (m) is used the period gets smaller (takes less time to complete a cycle) if a stronger spring (larger k) is used Period T = in seconds the time to complete a full cycle does not depend on where the oscillator is started (period is independent of amplitude)

Resonance effects all systems have certain natural vibration tendencies the mass/spring system oscillates at a certain frequency determined by its mass, m and the spring stiffness constant, k When you push a child on a swing you are using resonance to make the child go higher and higher.

How resonance works resonance is a way of pumping energy into a system to make it vibrate in order to make it work the energy must be pumped in at a rate (frequency) that matches one of the natural frequencies that the system likes to vibrate at. you pump energy into the child on the swing by pushing once per cycle The Tacoma Narrows bridge was set into resonance by the wind blowing over it

resonance examples two tuning forks resonance reeds shattering the glass

Waves What is a wave? A disturbance that moves (propagates) through something The “wave” - people stand up then sit down, then the people next to them do the same until the standing and sitting goes all around the stadium. the standing and sitting is the disturbance notice that the people move up and down but the disturbance goes sideways !

Homer trips and creates a longitudinal wave

a mechanical wave is a disturbance that moves through a medium ( e.g. air, water, strings)  waves carry energy  they provide a means to transport energy from one place to another electromagnetic waves (light, x-rays, UV rays, microwaves, thermal radiation) are disturbances that propagate through the electromagnetic field, even in vacuum (e.g. light from the Sun)

Mechanical waves a disturbance that propagates through a medium waves on strings waves in water – ocean waves – ripples that move outward when a stone is thrown in a pond sound waves – pressure waves in air

transverse wave on a string jiggle the end of the string to create a disturbance the disturbance moves down the string as it passes, the string moves up and then down the string motion in vertical but the wave moves in the horizontal (perpendicular) direction  transverse wave this is a single pulse wave (non-repetitive) the “wave” in the football stadium is a transverse wave

Wave speed: How fast does it go? The speed of the wave moving to the right is not the same as the speed of the string moving up and down. (it could be, but that would be a coincidence!) The wave speed is determined by: the tension in the string  more tension  higher speed the mass per unit length of the string (whether it’s a heavy rope or a light rope)  thicker rope  lower speed

Harmonic waves – keep jiggling the end of the string up and down

Slinky waves you can create a longitudinal wave on a slinky instead of jiggling the slinky up and down, you jiggle it in and out the coils of the slinky move along the same direction (horizontal) as the wave

SOUND WAVES longitudinal pressure disturbances in a gas the air molecules jiggle back and forth in the same direction as the wave the diaphragm of the speaker moves in and out

Sound – a longitudinal wave

The pressure waves make your eardrum vibrate we can only hear sounds between 30 Hz and 20,000 Hz below 30 Hz is called infrasound above 20,000 is called ultrasound

I can’t hear you! Since sound is a disturbance in air, without air (that is, in a vacuum) there is no sound. vacuum pump There is no sound in outer space!