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A 3.00 meter long string oscillates in the standing wave pattern shown to the right with...
A 3.00 meter long string oscillates in the standing wave pattern shown to the right with a wave speed of 100 m/s. What is the fundamental frequency for this string? 8.33 Hz O 16.7 Hz 25 Hz 1.67 Hz O 3.38 Hz
part 1. A 9.00-m long string sustains a three-loop standing wave pattern as shown. The string has a mass of 45 g and under a tension of 50 N. a. What is the frequency of vibration? b. At the same frequency, you wish to see four loops, what tension you need to use. Part 2. a. Determine the shortest length of pipe, open at both ends, which will resonate at 256 Hz (so the first harmonics is 256Hz). The speed...
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...
You generate a standing wave on a 1-m long string, fixed on both ends, by forcing it to vibrate at 100 Hz. When doing so, the standing wave has a wavelength of 1 m. According to the wave equation, v=Af, the speed of the wave along the string is 100 m/s. Suppose the forcing frequency is doubled to 200 Hz, without changing the length, tension or ends of the string. What is the new wavelength and wave speed? A. The...
The fundamental frequency of a standing wave on a 1.1-m-long string is 450Hz. What would be the wave speed of a pulse moving along this string?
A tube, open at the left end and closed at the right, has standing-wave patterns at frequencies of 198 Hz and 330 Hz. The speed of sound in air is 343 m/s. The lowest two harmonics (normal modes) that these two standing waves could be are m = and The frequency of the fundamental (m = 1) is Hz. The wavelength of the fundamental mode is m. The tube is m long
A 6m long string is stretched out between two points so that is supports a wave speed of 40 m/s. The string is then shaken at one end with the frequency of 10 Hz to generate a standing wave pattern on it. Where will the nodes of this standing wave be located on the string?
A standing-wave pattern is observed in a thin wire with a length of 5.00 m. The wave function is y = 0.013 00 sin (?x) cos (90?t) where x and y are in meters and t is in seconds. (a) How many loops does this pattern exhibit? loop(s) (b) What is the fundamental frequency of vibration of the wire? Hz (c) If the original frequency is held constant and the tension in the wire is increased by a factor of...
How do I solve this? A 1.70 m long string has a standing wave with 2 loops at a frequency of 38.4 Hz. What is the speed of the waves in the string? (Unit- m/s) 2003-2049 Acellus Corponation. Al Rights Reserved
A violin string 40.00 cm long and fixed at both ends oscillates in its n = 1 mode. The speed of waves on the string is 280 m/s, and the speed of sound in air is 348 m/s. What is the frequency of the emitted sound wave? (Hz) What is the wavelength of the emitted sound wave? (m)