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 46 g oscillating mass is given byx(t)=(2.0cm)cos13t, where t is in seconds....

The position of a 46 g oscillating mass is given byx(t)=(2.0cm)cos13t, where t is in seconds. Determine the amplitude. Determine the period. Determine the spring constant. Determine the maximum speed. Determine the total energy Determine the velocity at t = 0.43s

The position of a 47 g oscillating mass is given by x(t)=(1.7cm)cos13t, where t is in...

The position of a 47 g oscillating mass is given by x(t)=(1.7cm)cos13t, where t is in seconds. A: Determine the amplitude. B. Determine the period C. Determine the Spring constant. D. Determine the maximum speed. E. Determine the total energy. F. Determine the velocity at t = 0.45s I am able to check the answers, but I'm not sure what the process is to get the answer. Every method I try isn't getting me to the right answers. Answers are:...

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...

The position of a 48 g oscillating mass is given by x(t)=(1.7cm)cos11t, where t is in...

The position of a 48 g oscillating mass is given by x(t)=(1.7cm)cos11t, where t is in seconds. Determine the velocity at t = 0.42 s .

12. A 0.85-kg mass is attached to a spring that oscillates on a frictionless surface. The...

12. A 0.85-kg mass is attached to a spring that oscillates on a frictionless surface. The position of the oscillating mass is expressed as x(t) = 0.25 sin(5.5t), where x is in meters and t is in seconds. a) What is the amplitude? b) What is the period? c) What is the spring constant? d) What is the total energy of the system?

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.) 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?

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.

Horizontal Block-Spring mass system, x= 2.0m Sin (3.0t) t is in seconds. (a) find the period...

Horizontal Block-Spring mass system, x= 2.0m Sin (3.0t) t is in seconds. (a) find the period and frequency (b) find the speed, position and acceleration at t=2.4. (c) find the mechanical energy of the system, spring constant and amplitude. Thank you in advance.

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

The position of a mass oscillating on a spring is given by x=(7.2cm)cos[2πt/(0.78s)]. What is the frequency of this motion? When is the mass first at the position x=−7.2cm?