A body of unknown mass is tied to an ideal spring with 164 N / m...

A 0.500-kg mass attached to an ideal massless spring with a spring constant of 12.5 N/m...

A 0.500-kg mass attached to an ideal massless spring with a spring constant of 12.5 N/m oscillates on a horizontal, frictionless surface. At time t = 0.00 s, the mass is located at x = –2.00 cm and is traveling in the positive x-direction with a speed of 8.00 cm/s. PART A: Find the angular frequency of the oscillations. Express your answer in rad/s. PART B: Determine the amplitude of the oscillations. Express your answer with the appropriate SI units....

When a 0.770 kg mass oscillates on an ideal spring, the frequency is 1.32 Hz ....

When a 0.770 kg mass oscillates on an ideal spring, the frequency is 1.32 Hz . part a) What will the frequency be if 0.270 kg are added to the original mass? Try to solve this problem without finding the force constant of the spring. part b) What will the frequency be if 0.270 kg are subtracted from the original mass? Try to solve this problem without finding the force constant of the spring.

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 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 body of mass m = 18.6 kg is attached to a spring with force constant...

A body of mass m = 18.6 kg is attached to a spring with force constant k = 14.3 N/m. This body, which is initially at its equilibrium position, is given an initial velocity of v = 7.8 m/s. What is the speed of this body when it is at position x = - 2.0 m? An object starting at rest rotates with constant angular acceleration α = 0.3 rad/s2 . What is the angular displacement after t = 3.0...

a body mass m = 2.025 kg is suspended by an ideal spring. At equilibrium the...

a body mass m = 2.025 kg is suspended by an ideal spring. At equilibrium the spring elongation is y0 = 2.5 cm. The upper end of the spring is subjected to a harmonic oscillation movement with amplitude A = 1 mm. The oscillator quality factor is Q = 15. Determine: a) the own pulsation of the oscillator b) the amplitude of the forced oscillations when the oscillator's own pulse is equal to the pulsation of the external force

When a mass of m = 254 g is attached to a spring and the mass-spring...

When a mass of m = 254 g is attached to a spring and the mass-spring system is set into oscillatory motion, the period of the motion is T = 0.427 s. Determine the following. (a) frequency of the motion in hertz Hz (b) force constant of the spring N/m (c) amplitude of the oscillation, if the total energy of the oscillating system is 0.288 J m

A mass and spring system has mass m = 1.2 kg. The spring constant is unknown....

A mass and spring system has mass m = 1.2 kg. The spring constant is unknown. Also, neglect friction for this system. A) When the system is compressed by 1.00 cm and let go the frequency of the periodic motion is 0.75 Hz. What is the value of the spring constant k? B) What is the maximum speed vmax of the motion? C) What is the total energy TE = PE + KE in the system?

A mass of 1.79 kg is placed on a spring with spring constant of 280 N/m....

A mass of 1.79 kg is placed on a spring with spring constant of 280 N/m. After being pulled to its positive amplitude position and released, the resulting simple harmonic motion has a maximum velocity of 1.126 m/s. (a) Calculate the angular frequency of the oscillation.   rad/s (b) Calculate the minimum time elapsed for the mass to reach the 0.044 m position (distance from the equilibrium position).    s (c) Calculate the velocity of the mass at the time found in part (b).    m/s

A metal body with a mass 4.50 kg is connected to a spring with a force...

A metal body with a mass 4.50 kg is connected to a spring with a force constant of 475 N/m, and it oscillates horizontally with an amplitude of 2.20 cm. (a) What is the total mechanical energy (in J) of the body–spring system? J (b) What is the maximum speed (in m/s) of the oscillating body? m/s (c) What is the maximum magnitude of acceleration (in m/s2) of the oscillating body