The position of a mass oscillating on a spring is given by x=(7.2cm)cos[2πt/(0.78s)]. What is the...

13.7 The equation for the position as a function of time for an oscillating spring is...

13.7 The equation for the position as a function of time for an oscillating spring is given by x  30cmcos 25t where x is in centimeters when t is in seconds. a) What is the frequency? b) If the mass on the spring is 1.2 kg, what is the spring constant of the spring? c) What is the position at t = 0.025 s? d) What is the position at t = 0.09 s ? 13.8 The maximum potential...

A mass on a spring is set oscillating by first compressing the spring 3cm in the...

A mass on a spring is set oscillating by first compressing the spring 3cm in the negative direction, then releasing the mass from rest. The period of oscillation is 1s. Which equation(s) best describes the position as a function of time? Select one or more: A. x = 3cm cos(2π t +π) B. x = -3cm cos(2π t + 0 ) C. x = 3cm cos(2π t + π/2 ) D. x = 3cm cos(2π t - π/2 )

Motion of an oscillating mass [0.75 kg] attached to the spring is described by the equation...

Motion of an oscillating mass [0.75 kg] attached to the spring is described by the equation below: (??) = 7.4 (????) ?????? [(4.16 ?????? ?? ) ?? ? 2.42] Find: a. Amplitude b. Frequency c. Time Period d. Spring constant e. Velocity at the mean position f. Potential energy g. at the extreme position.

A mass is attached to the end of a spring and set into oscillation on a...

A mass is attached to the end of a spring and set into oscillation on a horizontal frictionless surface by releasing it from a stretched position. The position of the mass at any time is described by x = (6.6 cm)cos[2?t/(1.58 s)]. Determine the following. (a) period of the motion s (b) frequency of the oscillations Hz (c) first time the mass is at the position x = 0 (d) first time the mass is at the site of maximum...

A mass of 100 g is attached to a spring and oscillating with simple harmonic motion....

A mass of 100 g is attached to a spring and oscillating with simple harmonic motion. The position of the mass at all times is given by x(t) = (2.0 cm) cos(2t), where t is in seconds, and the 2 is in rad/s. Determine the following: (a) The amplitude (in cm). cm (b) The frequency. Hz (c) The maximum speed in cm/s. Think about the expression you can write for v(t). Where is the maximum velocity in that expression? You...

The position of a 55 gg oscillating mass is given by x(t)=(1.5cm)cos10tx(t)=(1.5cm)cos⁡10t, where tt is in...

The position of a 55 gg oscillating mass is given by x(t)=(1.5cm)cos10tx(t)=(1.5cm)cos⁡10t, where tt is in seconds. What is the amplitude, period, spring constant, maximum speed, total energy and velocity at T=.36s.

a.) A 100 g mass is oscillating on a spring with a spring constant of 3.0...

a.) A 100 g mass is oscillating on a spring with a spring constant of 3.0 N/m. The mass is initially at 15 cm from the equilibrium position with an initial speed of 80 cm/s. What is the oscillation amplitude? b.) A 200 g mass is oscillating on a spring with a spring constant of 4.0 N/m. The mass is initially at 15 cm from the equilibrium position with an initial speed of 50 cm/s. What is its maximum speed?

You hang a 175 g mass on a spring and start it oscillating with an amplitude...

You hang a 175 g mass on a spring and start it oscillating with an amplitude of 7 cm and a phase constant of −π/3. a. If the spring stretched 16 cm when you first hang the mass on it, how long will one oscillation take? b. Draw a position vs. time graph for two cycles of motion. Consider the position y = 0 to be the equilibrium position of the mass hanging on the spring. c. Will the velocity...

A mass of 0.12 kg is attached to a spring and set into oscillation on a...

A mass of 0.12 kg is attached to a spring and set into oscillation on a horizontal frictionless surface. The simple harmonic motion of the mass is described by x(t) = (0.42 m)cos[(14 rad/s)t]. Determine the following. (a) amplitude of oscillation for the oscillating mass (b) force constant for the spring (c) position of the mass after it has been oscillating for one half a period (d) position of the mass one-third of a period after it has been released...

The position of a particle in cm is given by x = (9) cos 3πt, where...

The position of a particle in cm is given by x = (9) cos 3πt, where t is in seconds. (a) What is the frequency? Hz (b) What is the period? s (c) What is the amplitude of the particle's motion? cm (d) What is the first time after t = 0 that the particle is at its equilibrium position? s In what direction is it moving at that time? * in the positive direction * in the negative direction