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Resonance Clicker questions by Trish Loeblein and Mike Dubson

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1 Resonance Clicker questions by Trish Loeblein and Mike Dubson
Learning Goals: Students will be able to: Describe what resonance means for a simple system of a mass on a spring. Identify, through experimentation, cause and effect relationships that affect natural resonance of these systems. Give examples of real-world systems to which the understanding of resonance should be applied and explain why. (not addressed in CQs)

2 1. Which system will have the lower resonant frequency?
Mass (kg) 2.5 5.0 Spring constant (N/m) 100 B because of the heavier mass. Some students may select C since the spring constants are equal. Use the sim to show the students. A) 1 B) 2 C) Same frequency

3 2. Which system will have the lower resonany frequency?
Mass (kg) 5.0 Spring constant (N/m) 200 100 B because of the lower spring constant. Some students may select C since the masses are equal. Use the sim to show the students. 1 has 1 hz and 2 has .7hz A) 1 B) 2 C) Same frequency.

4 3. Which system will have the lower resonance frequency?
Mass (kg) 3.0 Spring constant (N/m) 400 Driver Amplitude (cm) 0.5 1.5 C amplitude of the driver is an independent variable of frequency A) 1 B) 2 C) Same frequency.

5 4. Which best describes how the motion of the masses vary?
Less driver amplitude results in greater max height & faster oscillation More driver amplitude results in greater max height & faster oscillation Less driver amplitude results in greater max height More driver amplitude results in greater max height Mass (kg) 3.0 Spring constant (N/m) 400 Driver Amplitude (cm) 0.5 1.5 D amplitude of the driver is directly related to oscillation distance (A and B include another way to relate frequency; the frequency is not dependent on driver amplitude)

6 The steady-state amplitude is .. smallest at the highest driver f.
4. If the frequency f of the driver is not the same as the resonant frequency, which statement is most accurate? The steady-state amplitude is .. smallest at the highest driver f. largest at the highest driver f. is largest at driver f nearest the resonant frequency. is independent of driver f. C

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