The position of a 52 g oscillating mass is given by x(t)=(1.8cm)cos13t, where t is in seconds. Determine the velocity at t = 0.35 s .
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The position of a 52 g oscillating mass is given by x(t)=(1.8cm)cos13t, where t is in...
The position of a 52 g oscillating mass is given by x(t)=(1.8cm)cos13t, where t is in seconds. a) Determine the total energy. b) Determine the velocity at t = 0.35 s .
The position of a 52 g oscillating mass is given by x(t)=(1.8cm)cos10t , where t is in seconds. Determine the velocity at t = 0.41 s . Express your answer in meters per second.
The position of a 53 g oscillating mass is given by x(t)=(1.7cm)cos12t, 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 .45s
A. The position of a 45 g oscillating mass is given by x(t)=(2.0cm)cos(10t), where t is in seconds. Determine the velocity at t=0.40s. B. Assume that the oscillating mass described in Part A is attached to a spring. What would the spring constant k of this spring be? C. What is the total energy E of the mass described in the previous parts?
The position of a 48 g oscillating mass is given by x (t) (1.5 cm) cos 10t, where t is in seconds. Part F Determine the velocity at t = 0.38 S. Express your answer in meters per second. ΑΣφ ? m/s Previous Answers Request Answer Submit Incorrect; Try Again; 2 attempts remaining
Part A: The position of a 55 g oscillating mass is given by x(t)=(2.0cm)cos(10t), where t is in seconds. Determine the velocity at t=0.40s. Express your answer in meters per second to two significant figures. Part B: Assume that the oscillating mass described in Part A is attached to a spring. What would the spring constant k of this spring be? Express your answer in newtons per meter to two significant figures. Part C: What is the total energy E...
The position of a mass (350 g) attached to an oscillating spring is given by: x = 22.5 cm cos((7.84 rad/s) t) Find total energy of the mass. Determine the potential energy when the mass is located 5.3 cm from equilibrium. What is the velocity of the mass at the location in part B? Find the location of the mass when the velocity is one-third of its maximum value.
The position of a mass oscillating on a spring is given by the equation x(t) = A * sin(f t) , where A and fare constants. What are the dimensions of fif the argument of the sinc function is in degrees?
In-Class Assignment 2. The figure shows a position-versus-time graph for an oscillating mass m = 0.5 kg. x (cm) 20 10 0 -10 -20 I(s) 4 a. Determine the period of the motion. b. Determnine the angular frecquemcy of the motion c. Determine the amplitude of the motion. d. Determine the phase constant of the motion. e. Determine the maximum speed of the mass. f. Determine the maximum acceleration of the mass. g. Determine the total energy of the system....
The position as a function of time of a mass at the end of a spring that is undergoing SHM is given by x(t)=Asin( ωt+θ ). At time t=0.00 seconds, the oscillating mass-spring system has a displacement x=2.83 cm and a velocity v= 3.25cm/s. It is oscillating with an angular frequency of 2.64 radians per second. Determine the constants A and θ .