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Today 1/24. HW: 1/23 Handout “Beats and Boundaries” due Wednesday 1/29 Today: Beats 17.4 Reflections at Boundaries 27.3 Monday: Thin Film Interference 27.3 Labs start Monday. Next Week’s Lab: Microwaves. A wave in the “electric field” Reflection and transmission from and through wood
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Today 1/24 • HW: 1/23 Handout “Beats and Boundaries” due Wednesday 1/29 • Today:Beats 17.4Reflections at Boundaries 27.3 • Monday: Thin Film Interference 27.3 • Labs start Monday
Next Week’s Lab: Microwaves • A wave in the “electric field” • Reflection and transmission from and through wood • Reflection from metal (why metal is bad in your microwave) • Polarization (see section 24.6) • Interference (Young’s Double Slit)
Beats • Occur when the frequencies of the sources are not the same • Frequencies must be close • Locations for constructive interference move over time • Causes sound to get loud and soft • fb “beat frequency” depends on source frequency difference
10 Hz 12 Hz 0.5 s 2 Hz
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2
Sources emitting different frequencies. In this case they are alternately in and out of phase as time goes by. c Source 1 Source 2 Now the locations of constructive (and destructive) interference move in time. A stationary listener hears “Beats.”
Beats fb = f1 - f2 The beat frequency tells you the difference between the two source frequencies.
You want to know the frequency of a tuning fork. You test it by playing it at the same time as a tuning fork with a known frequency of 342 Hz and you hear beats at a rate of 5 per second. You then play it at the same time as one with a known frequency of 349 Hz and the beats are heard at a rate of 12 per second. What is the frequency of the tuning fork? a. 347 Hz b. 361 Hz c. 345.5 Hz d. 337 Hz e. 354 Hz.
Fixed end Light to heavy Free end Heavy to light Reflections at Boundaries • Four situations
Fixed End Reflections Crest turns into trough Leading edge is the same Fixed end Same velocity, length, and amplitude See “Wave Interference” handout for how the string looks during the reflection.
Free End Reflections Crest stays a crest Leading edge is the same Free end Same velocity, length, and amplitude See “Wave Interference” handout for how the string looks during the reflection.
Light to Heavy Both transmission and reflection Boundary feels like a fixed end to the light string Reflection just like fixed end, inverted Transmitted wavelength has the same shape except it’s shorter in length because it travels slower than the incoming wave. Slower, so not as far from boundary Inverted wave Shorter, “bunched up”
Heavy to Light Both transmission and reflection Boundary feels like a free end to the heavy string Reflection just like free end, not inverted Transmitted wavelength has the same shape except it’s longer in length because it travels faster than the incoming wave. Faster, farther from boundary Wave not inverted Longer, “spread out”
Light: Glass to Air Faster, farther from boundary Same as incoming wave Longer, “spread out” Light: Air to Glass Slower, so not as far from boundary Inverted wave Shorter, “bunched up”