Chapter 13 Objectives Explain why resonance occurs.

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Presentation transcript:

Chapter 13 Objectives Explain why resonance occurs. Section 2 Sound Intensity and Resonance Chapter 13 Objectives Explain why resonance occurs.

Forced Vibrations and Resonance Section 2 Sound Intensity and Resonance Chapter 13 Forced Vibrations and Resonance If one of the pendulums is set in motion, its vibrations are transferred by the rubber band to the other pendulums, which will also begin vibrating. This is called a forced vibration. Forced Vibration: A vibration caused by an oscillating (or vibrating) force. Each pendulum has a natural frequency based on its length. Natural Frequency: The frequency an object naturally vibrates at.

Forced Vibrations and Resonance, continued Section 2 Sound Intensity and Resonance Chapter 13 Forced Vibrations and Resonance, continued Resonance occurs when the frequency of a force applied matches the natural frequency of the system, resulting in a large amplitude of vibration. If one blue pendulum is set in motion, only the other blue pendulum, whose length is the same, will eventually resonate.

Section 2 Sound Intensity and Resonance Chapter 13 Resonance

Chapter 13 Section 3 Harmonics Objectives Differentiate between the harmonic series of open and closed pipes. Calculate the harmonics of a vibrating string and of open and closed pipes. Relate harmonics and timbre. Relate the frequency difference between two waves to the number of beats heard per second.

Fundamental Frequency Chapter 13 Section 3 Harmonics Fundamental Frequency A bridge too far

Standing Waves on a Vibrating String Chapter 13 Section 3 Harmonics Standing Waves on a Vibrating String The vibrations on the string of a musical instrument usually consist of many standing waves, each of which has a different wavelength and frequency. The greatest possible wavelength on a string of length L is l = 2L. The fundamental frequency, which corresponds to this wavelength, is the lowest frequency of vibration.

Chapter 13 Section 3 Harmonics The Harmonic Series

Standing Waves on a Vibrating String, continued Chapter 13 Section 3 Harmonics Standing Waves on a Vibrating String, continued Each harmonic is an integral multiple of the fundamental frequency. The quality of a musical tone of a certain pitch results from a combination of harmonics

Standing Waves in an Air Column Chapter 13 Section 3 Harmonics Standing Waves in an Air Column If both ends of a pipe are open, there is an antinode at each end. If one end of a pipe is closed, there is a node at that end. With an antinode at one end and a node at the other end, a different set of standing waves occurs.

Harmonics of Open and Closed Pipes Chapter 13 Section 3 Harmonics Harmonics of Open and Closed Pipes