A standing wave with five antinodes is excited in a string of length 2.5 m where the wave speed is 100.0 mjs. \Vhat is the frequency of the oscillations in the string?
A standing wave with five antinodes is excited in a string of length 2.5 m where...
General problems 1. A string with a length of 2.5 m resonates in five loops as shown above. The string linear density is 0.05 kg/m and the suspended mass is 0.5 kg a. What is the wavelength? b. What is the wave speed? c. What is the frequency of oscillations? d. What will happen to the number of loops if the suspended mass is increased?
the wave speed of a string of length L with both ends fixed is v=600 m/s . the frequency of oscillation of the standing wave with three antinodes is f=1200 hz. find the length of the string.
A string is stretched to a length of 1.2 m and a standing wave is produced with a speed of 4 m/s. The pattern for the standing wave is that of one anti-node between two nodes. What is the frequency that produces a standing wave? Include a diagram of the standing wave
Consider the standing wave pattern with 4 antinodes. This standing wave is on a wire of linear mass density 3g/m and length 2m. It is being driven by a magnetic vibrator on the end of the wire, wiggling the wire up and down at 120 Hz, find tension. The answer must be in Newton. The tension is now slowly increased, causing the standing wave pattern shown to disappear. At certain higher tension the next standing wave pattern appears. Tell how...
The standing wave is formed in a string with two fixed ends. The mass of the string is 20.0 g and a length of 8.0 m. The tension in the string is 40.0 N. Determine the positions of the nodes and antinodes for the third harmonic. nodes: antinodes: What is the vibration frequency for this harmonic?
A standing wave on a string that is fixed at both ends has frequency 80.0 Hz. The distance between adjacent antinodes of the standing wave is 16.0 cm. What is the speed of the waves on the string, in m/s?
The standing wave is formed in a string with two fixed ends. The mass of the string is 20.0 g and a length of 8.0 m. The tension in the string is 40.0 N. (a) Determine the positions of the nodes and antinodes for the third harmonic. nodes: antinodes: (b) What is the vibration frequency for this harmonic?
jcs eing assessed Nsole difficult we problems Eight antinodes are found in a vibrating string. What frequency would give a wave that travels the length of the string in 35 s? A 2.5-m long tube is filled partway with water. A 12-cm the tube, above the air in the tube. The string is cked and resonates at its f of 0024 kg and a tension of 140 N. If the plucked string makes the air in the tube resonate at...
In the standing waves experiment, the string has a mass of 44.5 g string and length of 1.18 m. The string is connected to a mechanical wave generator that produce standing waves with frequency of f. The other end of the string is connected to a mass holder (mholder = 50.0 g) that carries a weight of 5.00x102 g. Calculate the the frequency of the mechanical wave generator f, if the number of antinodes was 2. (g = 9.80 m/s2)
Adjacent antinodes of a standing wave of a string are 20.0 cm apart. A particle at an antinode oscillates in simple harmonic motion with amplitude 0.600 cm and period 0.100 s. The string lies along the +x-axis and its left end is fixed at x = 0. The string is 70.0 cm long. At time t = 0, the first antinode is at maximum positive displacement. a. Is the right end of the string fixed or free? Explain. b. Sketch...