3. Suppose we attach a mass of 200.0g to the end of an ideal spring whose spring constant k is 5.60 N/m, and pull it back from equilibrium a distance A=25.0 cm a. What is the angular frequency? b. What is the period? c. What is the frequency in Hertz ? d. What is the maximum speed ? e. what is the magnitude of the maximum acceleration ? f. What is the magnitude of the restoring force on the spring at the maximum displacement? Some potentially useful equations: k W = т 1 T =-= X(t) = A cos(wt) V(t) = -Aw sin(wt); Vmax = Aw A(t) -Aw? sin(wt); Amax = Aw?

3. Suppose we attach a mass of 200.0g to the end of an ideal spring whose spring constant k is 5.60 N/m, and pull it back from equilibrium a distance A=25.0 cm a. What is the angular frequency? b. What is the period? c. What is the frequency in Hertz ? d. What is the maximum speed ? e. what is the magnitude of the maximum acceleration ? f. What is the magnitude of the restoring force on the spring at the maximum displacement? Some potentially useful equations: k W = т 1 T =-= X(t) = A cos(wt) V(t) = -Aw sin(wt); Vmax = Aw A(t) -Aw? sin(wt); Amax = Aw?

Physics for Scientists and Engineers with Modern Physics

10th Edition

ISBN:9781337553292

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter15: Oscillatory Motion

Section: Chapter Questions

Problem 21P

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