The speed of a wave in a string is given by v = sqrt(FT/μ), where FT is the tension in the string and μ = mass/length of the string.
A 2.00 m long string has a mass of (A+1.50) g. A (B+25.0) g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of (125+C) Hz. Find the wavelength for the wave generated. Give your answer in centimeters (cm) and with 3 significant figures.
A=8
B=206
C=6
The speed of a wave in a string is given by v = sqrt(FT/μ), where FT...
The speed of a wave in a string is given by v = √(FT/μ), where FT is the tension in the string and μ = mass / length of the string. A 2.00 m long string has a mass of (A+1.50) g. A (B+25.0) g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of (125+C) Hz. Find the...
The speed of a wave in a string is given by v = √(FT/μ), where FT is the tension in the string and μ = mass / length of the string. A 2.00 m long string has a mass of 20.50 g. A 980 g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of 130 Hz. Find the...
A 2.00 m long string has a mass of 15.50 g. A 696 g mass is attached to the string and hung over a pulley (see illustration from one of the team problems). The end of the string is then vibrated at a frequency of 126 Hz. Find the wavelength for the wave generated. Give your answer in centimeters (cm) and with 3 significant figures.
A 2.00 m long string has a mass of 15.50 g. A 606 g mass is attached to the string and hung over a pulley. The end of the string is then vibrated at a frequency of 126 Hz. Find the wavelength for the wave generated. Give your answer in centimeters (cm) and with 3 significant figures.
A standing wave pattern is created on a string with mass density u- 3x 10 kg/m. A wave generator with frequency f- 65 Hz is attached to one end of the string and the other end goes over a pulley and is connected to a mass (ignore the weight of the string between the pulley and mass). The distance between the generator and pulley is L- 0.74 m. Initially the 3rd harmonic wave pattern is formed. What is the wavelength...
6. The speed v of waves on a string is given by v (F/)12, where F is the tension and H m/L is the mass per unit length of the string. If you double the wavelength λ of a wave on a string, what happens to the wave speed v and the wave frequency f?
DQuestion 5 1 pts A simple harmonic oscillator at the point x-0 generates a wave on a horizontal rope. The oscillator operates at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. The rope has a linear mass density of 50.0 g/m, and is stretched with a tension of 5.00 N. Find the maximum transverse acceleration of points on the rope, in m/s? Sample submission: 1230 Note: your answer should be much larger than g. which is...
A string of mass per unit length μ 1 g/nn is stretched to a tension of T = 20 N. A wave is induced on the string of wavelength λ 0.5 m. Find the frequency of the wave (f =?) Problem 3: n air column closed at one end and open at another end vibrates at a fundamental frequency of f = 261.6 Hz. What is the length of the air column (L) Problem 4 A child cries with an...
question 4-7
4. Travelling Waves and Their Characteristics A rope wave travels in the positive x -direction. You are also told that the speed of the wave is 1000 cm/s, its frequency is 200 Hz, and that the wave is subject to the following initial conditions: at x 0 and t = 0: y =-1 cm, and, at x = 0 and t : ar = +20 cm/s (this is the velocity of the point on the rope at horizontal...