3. Derive the expression for the period of an oscillating mass attached to a spring using...

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.

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

the period of an object attached to a spring oscillating on an inclined plane(no friction) depends...

the period of an object attached to a spring oscillating on an inclined plane(no friction) depends on

A mass of 0.520 kg is attached to a spring and set into oscillation on a...

A mass of 0.520 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) = (0.780 m)cos[(18.0 rad/s)t]. Determine the following. (a) amplitude of oscillation for the oscillating mass (b) force constant for the spring N/m (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...

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...

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...

A mass of 0.380 kg is attached to a spring and set into oscillation on a...

A mass of 0.380 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) = (0.800 m)cos[(10.0 rad/s)t]. Determine the following. (a) amplitude of oscillation for the oscillating mass ____m (b) force constant for the spring ____ N/m (c) position of the mass after it has been oscillating for one half a period ______ m (d) position of the mass one-sixth of a period...

A mass of 187 g is attached to a spring and set into simple harmonic motion...

A mass of 187 g is attached to a spring and set into simple harmonic motion with a period of 0.286 s. If the total energy of the oscillating system is 6.94 J, determine the following. (a) maximum speed of the object m/s (b) force constant N/m (c) amplitude of the motion m

Confirm that the expression for the period of the simple harmonic motion of an object of...

Confirm that the expression for the period of the simple harmonic motion of an object of mass m attached to a spring of force constant k is dimensionally correct.

3. Consider a mass m attached to a horizontal spring with spring constant k.  Suppose the mass...

3. Consider a mass m attached to a horizontal spring with spring constant k.  Suppose the mass is pulled a distance A from the equilibrium position.   a. Find the total energy at the amplitude in terms of k and A b. Using conservation of energy, find an expression for the maximum speed at the equilibrium position in terms of k, A and m