A 8.8-kg mass, m is hung from wire with a total length of 1.9-m and a mass of 5.50 grams.
If the mass hangs l=0.2 m below the pulley, what is the fundemental frequency at which the wire (L) will vibrate?
A 8.8-kg mass, m is hung from wire with a total length of 1.9-m and a...
In the arrangement shown below, an object can be hung from a
string (with linear mass density μ = 0.002 00 kg/m) that
passes over a light pulley. The string is connected to a vibrator
(of constant frequency f), and the length of the string
between point P and the pulley is L = 2.30 m.
When the mass m of the object is either 9.0 kg or 16.0 kg,
standing waves are observed; no standing waves are observed with...
A 10.9-kg object hangs in equilibrium from a string with a total
length of 6.00 m and a linear mass density of μ = 0.00300 kg/m. The
string is wrapped around two light frictionless pulleys that are
separated by a distance of d = 2.00 m.
ton (a) Determine the tension in the string. (b) At what frequency must the string between the pulleys vibrate in order to form the standing-wave pattern shown in Figure b?
An ideal spring hangs from the ceiling. A 1.25 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0285 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
An ideal spring hangs from the ceiling. A 1.45 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0275 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
A mass m = 0.4 kg is hung from a pulley with mass M = 0.20 kg and radius R = 10 cm. There is no friction in the pulley's axel. What is, approximately, the acceleration of the pulley? 1.0 m/s^2 5.2 m/s^2 10 m/s^2 8.0 m/s^2 40 m/s^2
An ideal spring hangs from the ceiling. A 1.45 kg mass is hung from the spring, stretching the spring a distance d 0.0845 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L-0.0295 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position? kinetic energy Equilibrium position
An ideal spring hangs from the ceiling. A 2.15 kg mass is hung from the spring, stretching the spring a distance d = 0.0865 m from its original length when it reaches equilibrium. The mass is then lifted up a distance L = 0.0235 m from the equilibrium position and released. What is the kinetic energy of the mass at the instant it passes back through the equilibrium position?
A wire of length 1.69 m and total mass 0.033 kg is fixed at its ends and held at tension T = 31.5 N. a. What is the velocity of a transverse wave on the wire? b. The wire vibrates at its fundamental frequency. What is the wavelength, λ, of the wave?
In the arrangement shown in the figure below, an object of mass
m = 2.0 kg hangs from a cord around a light pulley. The length of
the cord between point P and the pulley is L = 2.0 m. (Ignore the
mass of the vertical section of the cord.)
(a) When the vibrator is set to a frequency of 140 Hz, a
standing wave with six loops is formed. What must be the linear
mass density of the cord?...
An object with the mass m= 2.0 kg hangs from a cord around a light pulley. The length of the cord between point P and the pulley is L= 2.0 m (Ignore the mass of the vertical section of the cord) a) When the vibrator is set to a frequency of 160 Hz, a standing wave with six loops is formed. What must be the linear mass density of the cord in kg/m? b) How many loops (if any) will...