13. A 6.800-kg bowling ball sits upon a dolly of negligible mass and wheel-friction, and is attached to a wall by a spring with spring constant 454 N/m. The bowling ball is pulled away from the wall by 9.88 cm and released while still moving at 0.803 m/s. (i) What are the angular frequency, frequency, and period of the bowling ball's ensuing motion? (ii) What will be the bowling ball's maximum displacement from equilibrium? (iii) With what speed will the bowling ball pass through its equilibrium point? (iv) At what location(s), relative to the equilibrium point, will the ball have a speed of 0.921 m/s? Where will be bowling ball be exactly one minute after it was set in motion? When will the bowling ball pass through the equilibrium point for the first time since its release?

13. A 6.800-kg bowling ball sits upon a dolly of negligible mass and wheel-friction, and is attached to a wall by a spring with spring constant 454 N/m. The bowling ball is pulled away from the wall by 9.88 cm and released while still moving at 0.803 m/s. (i) What are the angular frequency, frequency, and period of the bowling ball's ensuing motion? (ii) What will be the bowling ball's maximum displacement from equilibrium? (iii) With what speed will the bowling ball pass through its equilibrium point? (iv) At what location(s), relative to the equilibrium point, will the ball have a speed of 0.921 m/s? Where will be bowling ball be exactly one minute after it was set in motion? When will the bowling ball pass through the equilibrium point for the first time since its release?

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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