Suppose on a string of length L=87 cm, tension T=115 N, and mass m the fundamental (1st Harmonic) has a frequency of f1= 500.0 Hz. a) What is the wavelength of the fundamental? b) What is the speed of propagation of the wave in the string? c) What is the mass m of the string? d) In order to tune the string to a new fundamental frequency of 505 Hz, how much does the tension need to change? Will it increase or decrease?
Suppose on a string of length L=87 cm, tension T=115 N, and mass m the fundamental...
A rope has a length of 5.00 m between its two fixed points and a mass per unit length (linear density) of 40.0 g / m. if the string vibrates at a fundamental frequency of 20 Hz. a) Calculate the tension of the string. b) Calculate the frequency and wavelength of the second harmonic (n = 2). c) Calculate the frequency and wavelength of the third harmonic. d) the speed of propagation of the wave.
algebra based physics 1. A steel guitar string has a mass per length of 0.720 g/m. If the length of the string between two fixed ends is 54.6 cm, what tension is needed for fundamental frequency of middle C (261.6 Hz)? a. What is the wavelength of the fundamental mode? b. What is the speed of the waves on the string? c. What tension is needed for the fundamental frequency? 2. Sketch the waveform of the third harmonic for a...
A transverse wave is traveling along a string of total mass M, length L, and tension T. Which of the following is correct? a. The wavelength of the wave is proportional to L. b. The wave velocity depends on M,L,and T. c. The frequency of the wave is proportional to the wavelength. d. The speed of motion of a point on the string is the same as the velocity of propagation of the wave.
The mass density of a 115 cm long, 0.724 mm diameter string is 1.85 x 10-4 kg/m. Determine the tension needed in the string to have the same fundamental frequency as E (330 Hz). If the diameter of the string were decreased to 0.699 mm, but the mass density remains the same, will the tension increase, decrease, or remain the same to produce the same E fundamental frequency? Explain. What is the length of a closed pipe necessary to have...
A string of mass 100 g and length 2 m is under a tension of 200 N. Find its (a) wave velocity, (b) fundamental frequency, (c) 3rd harmonic frequency, and (d) 5th overtone wavelength.
13.18 A string with a length of 125 cm and a mass of 2.15 g is stretched with a tension of 425 N a) What is the speed of waves on the string? b) What is the fundamental frequency of the string? c) What is the wavelength of the third harmonic? d) What is the frequency of the third harmonic?
A violin string of length 43 cm and mass 1.1 g has a frequency of 495 Hz when it is vibrating in its fundamental mode. (a) What is the wavelength of the standing wave on the string? cm (b) What is the tension in the string? N (c) Where should you place your finger to increase the frequency to 645 Hz? cm from the fixed end of the string (from the peg of the violin)
A violin string of length 44 cm and mass 1.1 g has a frequency of 534 Hz when it is vibrating in its fundamental mode. (a) What is the wavelength of the standing wave on the string? _______ cm (b) What is the tension in the string? _______N (c) Where should you place your finger to increase the frequency to 684 Hz? __________ cm from the fixed end of the string (from the peg of the violin)
A string of mass 100g and length 2m is under a tension of 200 N. Find its (a) wave velocity, (b) fundamental frequency, (c) 3rd harmonic frequency, and (d) 5th overtone wavelength.
A violin string of length 38 cm and mass 1.3 g has a frequency of 457 Hz when it is vibrating in its fundamental mode. (a) What is the wavelength of the standing wave on the string? cm (b) What is the tension in the string? N (c) here should you place your finger to increase the frequency to 607 Hz? cm from the fixed end of the string (from the peg of the violin) eBook