A 195 g mass attached to a horizontal spring oscillates at a frequency of 2.50 Hz...

A 205 g mass attached to a horizontal spring oscillates at a frequency of 1.00 Hz...

A 205 g mass attached to a horizontal spring oscillates at a frequency of 1.00 Hz . At t =0s, the mass is at x= 4.20 cm and has vx =− 23.0 cm/s . Determine: (a) the period s (b) the angular frequency rad/s (c) the amplitude cm (d) the phase constant rad (e) the maximum speed cm/s (f) the maximum acceleration cm/s2 (g) the total energy J (h) the position at t = 4.2s

A 245 g mass attached to a horizontal spring oscillates at a frequency of 1.30 Hz...

A 245 g mass attached to a horizontal spring oscillates at a frequency of 1.30 Hz . At t =0s the mass is at x= 4.20 cm and has vx=−=− 42.0 cm/s Determine the phase constant and max speed

A 255 g mass attached to a horizontal spring oscillates at a frequency of 5.50 Hz...

A 255 g mass attached to a horizontal spring oscillates at a frequency of 5.50 Hz . At t =0s, the mass is at x= 4.40 cm and has vx =− 34.0 cm/s . Determine: The period. The angular frequency. The amplitude. The phase constant.

A 240 g mass attached to a horizontal spring oscillates at a frequency of 5.20 Hz...

A 240 g mass attached to a horizontal spring oscillates at a frequency of 5.20 Hz . At t =0s, the mass is at x= 6.80 cm and has vx =− 27.0 cm/s . Determine: The period. Enter your answer numerically to five significant figures. The angular frequency. Enter your answer numerically to five significant figures. The amplitude. Enter your answer numerically to five significant figures. The phase constant. Enter your answer numerically to four significant figures.

A 200 g mass attached to a horizontal spring oscillates at a frequency of 2.0 Hz...

A 200 g mass attached to a horizontal spring oscillates at a frequency of 2.0 Hz . At one instant t=0s, the mass is at x=5.0cm and has V=−30cm/s. Determine the time that the mass passes through the equilibrium position for the first time.

A 4.00 kg mass on a frictionless horizontal surface is attached to a spring. The other...

A 4.00 kg mass on a frictionless horizontal surface is attached to a spring. The other end of the spring is fixed to a wall. The spring constant is 6.00 N/m. The mass is moved to the right, stretching the spring by 12.0 cm, and then released from rest. a) Find the frequency of the motion in Hz. b) Find the force when x = 6.00 cm. c) Find the time when x = 6.00 cm. d) Find the velocity...

A 400 gram mass is attached to a horizontal spring with a frequency of 2 Hz....

A 400 gram mass is attached to a horizontal spring with a frequency of 2 Hz. The mass has a speed of 40 cm/s and is located at x=5 cm.. A) find the period of motion B) find the amplitude of motion C) find the maximum speed of the mass D) find the total energy of the mass

A mass attached to a spring oscillates back and forth on a horizontal frictionless surface. The...

A mass attached to a spring oscillates back and forth on a horizontal frictionless surface. The velocity of the mass is modeled by the function v = 2πfA cos(2πft) when at t = 0, x = 0. What is the magnitude of the velocity in cm/s at the equilibrium position for an amplitude of 4.5 cm and a frequency of 2.3 Hz?

A 3.5kg mass is attached to an ideal spring (k = 100.0N/m) and oscillates on a...

A 3.5kg mass is attached to an ideal spring (k = 100.0N/m) and oscillates on a horizontal frictionless track. At t = 0.00s, the mass is released from rest at x = 15.0cm. a.) Determine the frequency (f) of the oscillations. b.) Determine the maximum speed of the mass. At what point in the motion does the maximum speed occur? c.) What is the maximum acceleration of this mass? At what point in the motion does the maximum acceleration occur?...

A 280-g object attached to a spring oscillates on a frictionless horizontal table with a frequency...

A 280-g object attached to a spring oscillates on a frictionless horizontal table with a frequency of 4.00 Hz and an amplitude of 25.0 cm. 1) Calculate the maximum potential energy of the system.(Express your answer to three significant figures.) 2) Calculate the displacement of the object when the potential energy is one-half of the maximum.(Express your answer to three significant figures.) 3) Calculate the potential energy when the displacement is 10.0 cm.(Express your answer to three significant figures.)