A 442 g object (block) is being pulled about 7.4 cm from its equilibrium position (rest)...

A 4.00 kg block hangs from a spring, extending it 16.0 cm from its unstretched position....

A 4.00 kg block hangs from a spring, extending it 16.0 cm from its unstretched position. (a.) What is the spring constant? = 245 N/m (b.) The block is removed, and a 0.500 kg mass is hung from the same spring. If the spring is then stretched and released, what is its period of oscillation? =.284 sec (c.) Write the unique equation of motion y(t) for the motion of the mass in part (b), assuming the mass was initially pulled...

A 3.90 kg block hangs from a spring with spring constant 1980 N/m . The block...

A 3.90 kg block hangs from a spring with spring constant 1980 N/m . The block is pulled down 5.40 cm from the equilibrium position and given an initial velocity of 1.80 m/s back toward equilibrium. What is the frequency of the motion? What is the amplitude? What is the total mechanical energy of the motion?

A 2.00-kg block lies at rest on a frictionless table. A spring, with a spring constant...

A 2.00-kg block lies at rest on a frictionless table. A spring, with a spring constant of 100 N/m, is attached to the wall and to the block. The second block of 0.50 kg is placed on top of the first one. The 2.00-kg block is gently pulled to a position x = + A and released from rest. There is a coefficient of friction of 0.45 between the two blocks. (a) Assuming that the top block does not slide,...

A mass is suspended on a spring, pulled downward from its equilibrium position, and released. Assume...

A mass is suspended on a spring, pulled downward from its equilibrium position, and released. Assume that t = 0 when the spring is released, and the frequency of oscillation is w. Assume a vertical coordinate system in which the coordinate y points upward (see diagram at left). Match the following physical quantities with their functional form. Vertical Acceleration d^2y/dt^2 Vertical Velocity dy/dt Vertical position y Total Energy    A. cos wt B. -sin wt C. Constant D. sin wt...

Answer each question and justify your answer in one or two sentences. Question 1 A block...

Answer each question and justify your answer in one or two sentences. Question 1 A block is attached to the end of a horizontal ideal spring and rests on a frictionless surface. The other end of the spring is attached to a wall. The block is pulled away from the spring’s unstrained position by a distance x0 and given an initial speed of v0 as it is released. Which one of the following statements concerning the amplitude of the subsequent...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A...

A particle with mass 2.61 kg oscillates horizontally at the end of a horizontal spring. A student measures an amplitude of 0.923 m and a duration of 129 s for 65 cycles of oscillation. Find the frequency, ?, the speed at the equilibrium position, ?max, the spring constant, ?, the potential energy at an endpoint, ?max, the potential energy when the particle is located 68.5% of the amplitude away from the equiliibrium position, ?, and the kinetic energy, ?, and...

A spring has an unstretched length of 10 cm. When a 150 g mass is added...

A spring has an unstretched length of 10 cm. When a 150 g mass is added the spring stretches to a total length of 15 cm, where the mass rests at equilibrium. What is the spring constant of the spring? Now the mass is pulled down by an additional 5 cm, so that the total length of the spring is 20 cm, and then released. What is the frequency and period of the subsequent oscillation? Draw a graph—including numbers on...

One example of simple harmonic motion is a block attached to a spring, pulled to one...

One example of simple harmonic motion is a block attached to a spring, pulled to one side, then released, so it slides back and forth over and over. In real experiments, friction and drag can't be eliminated, so both will do a small amount of negative work on the sliding mass, each cycle, slowly reducing its ME, until the block stops moving altogether. a) As the system's ME decreases, the block's maximum speed gets smaller, but the oscillation period T...

A spring has an unstretched length of 10 cm. When a 150 g mass is added...

A spring has an unstretched length of 10 cm. When a 150 g mass is added the spring stretches to a total length of 15 cm, where the mass rests at equilibrium. A. What is the spring constant of the spring? B. Now the mass is pulled down by an additional 5 cm, so that the total length of the spring is 20 cm, and then released. What is the frequency and period of the subsequent oscillation? C. Draw a...

A spring has an unstretched length of 10 cm. When a 150 g mass is added...

A spring has an unstretched length of 10 cm. When a 150 g mass is added the spring stretches to a total length of 15 cm, where the mass rests at equilibrium. A. What is the spring constant of the spring? B. Now the mass is pulled down by an additional 5 cm, so that the total length of the spring is 20 cm,and then released. What is the frequency and period of the subsequent oscillation? C. Draw a graph—including...