Problem 2.42 Use the approximation that V avg Pm for each time step A spring with...
Use the approximation that →avg-pfhn for each time step. A spring with a relaxed length of 25 cm and a stiffness of 20 N/m stands vertically on a table. A block of mass 63 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 31.6 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position...
Use the approximation that v→avg=p→f/m for each time step. A spring with a relaxed length of 25 cm and a stiffness of 16 N/m stands vertically on a table. A block of mass 89 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 30.3 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position...
Use the approximation that v→avg=p→f/m for each time step. A spring with a relaxed length of 25 cm and a stiffness of 16 N/m stands vertically on a table. A block of mass 89 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 30.3 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position...
Use the approximation that v→avg=p→f/m for each time step. A spring with a relaxed length of 25 cm and a stiffness of 17 N/m stands vertically on a table. A block of mass 75 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 30.9 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position...
Use the approximation that Vavg lm for each time step A spring with a relaxed length of 25 cm and a stiffness of 20 N/m stands vertically on a table. A block of mass 69 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 29.7 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the...
Problem 2.42 (Multistep) Use the approximation that Va for each time step A spring with a relaxed length of 25 cm and a stiffness of 12 N/m stands vertically on a table. A block of mass 67 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 29.1 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s,...
Use the approximation that for each time step. A spring with a relaxed length of 25 cm and a stiffness of 16 N/m stands vertically on a table. A block of mass 78 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 29.5 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position and...
A spring with a relaxed length of 25 cm and a stiffness of 15 N/m stands vertically on a table. A block of mass 86 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 29.9 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position and momentum of the block at a time 0.2...
A spring with a relaxed length of 25 cm and a stiffness of 13 N/m stands vertically on a table. A block of mass 73 g is attached to the top of the spring. You pull the block upward, stretching the spring until its length is now 31.7 cm, hold the block at rest for a moment, and then release it. Using a time step of 0.1 s, predict the position and momentum of the block at a time 0.2...
A block is attached to the top of a spring that stands vertically on a table. The spring stiffness is 57 N/m, its relaxed length is 31 cm, and the mass of the block is 305 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...