An oscillator with period 3.0 ms passes through equilibrium at t = 7.2 ms with velocity...
An oscillator with period 1.6 ms passes through equilibrium at t = 22.4 ms with velocity v = -2.1 m/s. The equation of the oscillator's motion is x(t) =[-------] cm cos ( ([---------] /s ) t +[--------] )
An oscillator with period 2.7 ms passes through equilibrium at t = 16.1 ms with velocity v =-6.0 m/s. The equation of the oscillator's motion is x(t) = Xcm cos 2327.4 s) t+ x ) Submit AnswerSave Progress Practice Another Version
A harmonic oscillator is described by the function x(t) = (0.260 m) cos(0.420t). Find the oscillator's maximum velocity and maximum acceleration. Find the oscillator's position, velocity, and acceleration when t = 1.25 s. (a) oscillator's maximum velocity (in m/s) m/s (b) oscillator's maximum acceleration (m/s2) m/s2 (c) oscillator's position (in m) when t = 1.25 s m (d) oscillator's velocity (in m/s) when t = 1.25 s m/s (e) oscillator's acceleration (in m/s2) when t = 1.25 s m/s2
O2/5 points Prevos Answes My Notes A harmonic oscillator is described t 2.25 s the function x(t) - (0.280 m) cos(0.500r). Find the oscillator's maximum velocity and maximum acceleration. Find the oscillator's position, velocity, and acceleration when HINT (a) oscllator's maximum velocity (in m/s) 14 m/s (b) oscillator's maximum acceleration (m/s2) 07 m/s2 (c) oscillator's position (in m) when t-2.25 s 27994 X m (d) oscillator's velocity (in m/s) when t 2.25 s x m/s 0027487 (e) 0scillator's acceleration (in...
A simple harmonic oscillator at the position x=0 generates a wave on a string. The oscillator moves up and down at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time t = 0, the oscillator is passing through the origin and moving down. The string has a linear mass density of 50.0 g/m and is stretched with a tension of 5.00 N. A simple harmonic oscillator at the position x = 0 generates a wave...
This scenario is for questions 1-2. A simple harmonic oscillator at the position x = 0 generates a wave on a string. The oscillator moves up and down at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time t = 0, the oscillator is passing through the origin and moving down. The string has a linear mass density of 50.0 g/m and is stretched with a tension of 5.00 N. a) Find the angular frequency...
The function x = (2.2 m) cos[(4πrad/s)t + π/3 rad] gives the simple harmonic motion of a body. At t = 3.0 s, what are the (a) displacement, (b) velocity, (c) acceleration, and (d) phase of the motion? Also, what are the (e) frequency and (f) period of the motion?
can you help with a-f please This scenario is for questions 1-2 A simple harmonic oscillator at the position x-Ogenerates a wave on a string. The oscillator moves up and down at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. At time t = 0, the oscillator is passing through the origin and moving down. The string has a linear mass density of 50,0 g/m and is stretched with a tension of 5.00 N. a) Find...
3. An oscillator is drawn out to an initial displacement and reaches the first equilibrium point in 65 s. A) What is the period of the oscillator? B) If the velocity is 44 m/s, what is the initial displacement of the oscillator? C) If the restoring force that started the motion is 43 N. what is the spring constant of the oscillator? D) What is the maximum velocity? E) What is the maximum acceleration?
An oscillator is drawn out to an initial displacement and reaches the first equilibrium point in 43 s. A) What is the period of the oscillator? B) If the velocity is 78 m/s, what is the initial displacement of the oscillator? C) If the restoring force that started the motion is 20 N, what is the spring constant of the oscillator? D) What is the maximum velocity? E) What is the maximum acceleration?