Use the approximation that u avg = P/m for each time step. A block is attached to the top of a spring that stands vertically on a table. The spring stiffness is 50 N/m, its relaxed length is 30 cm, and the mass of the block is 230 g. The block is oscillating up and down as the spring stretches and compresses. At a particular time you observe that the velocity of the block is <0, 0.0877, 0> m/s and the position of the block is <0, 0.0798, 0> m relative to an origin at the base of the spring. Using a time step of 0.1 s, determine the position of the block 0.2 s later. 7 = 0 eTextbook and Media 0.0916 0 > m

Use the approximation that u avg = P/m for each time step. A block is attached to the top of a spring that stands vertically on a table. The spring stiffness is 50 N/m, its relaxed length is 30 cm, and the mass of the block is 230 g. The block is oscillating up and down as the spring stretches and compresses. At a particular time you observe that the velocity of the block is <0, 0.0877, 0> m/s and the position of the block is <0, 0.0798, 0> m relative to an origin at the base of the spring. Using a time step of 0.1 s, determine the position of the block 0.2 s later. 7 = 0 eTextbook and Media 0.0916 0 > m

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter2: Motion In One Dimension

Section: Chapter Questions

Problem 55P: A man drops a rock into a well. (a) The man hears the sound of the splash 2.40 s after he releases...

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