A longitudinal wave with a frequency of 29.0 Hz takes 1.2 s to travel the length of a 3.2 m Slinky (see the figure). Determine the wavelength of the wave. Answer in m. Please provide a detailed answer. Thank you!
A longitudinal wave with a frequency of 29.0 Hz takes 1.2 s to travel the length...
A wave traveling on a Slinky® that is stretched to 4 m takes 4.19 s to travel the length of the Slinky and back again. (a) What is the speed (in m/s) of the wave? Using the same Slinky® stretched to the same length, a standing wave is created which consists of seven antinodes and eight nodes. At what frequency (in Hz) must the Slinky be oscillating?
A wave pulse travels down a slinky. The mass of the slinky is m = 0.87 kg and is initially stretched to a length L = 6.9 m. The wave pulse has an amplitude of A = 0.23 m and takes t = 0.482 s to travel down the stretched length of the slinky. The frequency of the wave pulse is f = 0.49 Hz. If the new wave pulse has the same frequency, what is the new wavelength?
A wave pulse travels down a slinky. The mass of the slinky is m = 0.94 kg and is initially stretched to a length L = 7.4 m. The wave pulse has an amplitude of A = 0.23 m and takes t = 0.412 s to travel down the stretched length of the slinky. The frequency of the wave pulse is f = 0.45 Hz. 3)What is the average speed of a piece of the slinky as a complete wave...
2. A sinusoidal wave is traveling along a rope. The oscillator that generates the wave completes 39.0 vibrations in 29.0 s. A given crest of the wave travels 410 cm along the rope in 14.0 s. What is the wavelength of the wave? 3. When a particular wire is vibrating with a frequency of 5.00 Hz, a transverse wave of wavelength 64.0 cm is produced. Determine the speed of waves along the wire.
Two wires, each of length 1.2 m, are stretched between two fixed supports. On wire A there is a second-harmonic standing wave whose frequency is 731 Hz. However, the same frequency of 731 Hz is the third harmonic on wire B. Find the speed at which the individual waves travel on each wire.
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
By wiggling one end, a sinusoidal wave is made to travel along a stretched string that has a mass per unit length of 22.0 g/m. The wave may be described by the wave function y 0.20 sin (0.90x-42) where x and y are in meters and t s in seconds. 1. (a) Determine the speed of the wave. Is the wave moving in the +x direction or the -x direction? b) What is the tension in the stretched string? (c)...
4. A 58.0-cm guitar string produces a sound wave with a fundamental frequency of 105 Hz. The speed of sound in air is 338 m/s. Determine the ratio of the wavelength of the waves that travel on the string to the wavelength of the generated sound wave. 2.78 0.360 0.180 0.721 5.55
A water wave has a frequency of 10 Hz and a length of 2.5 meters. What is the period of these waves? What is the wave velocity? What is the distance (in meters) traveled by a sound wave in 22 seconds as the wave moves through Air? A steel rail A 600 Hz sound has a velocity of 1087 ft/s in the air and 4920 ft/s in water. Find the wavelength of this sound: In air In water
Question 35 (1 point) A sound wave has a length of 0.66 meters. If the frequency of the wave is 512 Hz (high C), what is the wave velocity? Question 35 options: 511 m/sec 776 m/s 0.00129 m/s 338 m/s Question 36 (1 point) A standing wave on a string has a velocity of 42 m/s and a period of 0.01 s. What is the frequency of the wave? Question 36 options: 10 sec 0.42 Hz 100 Hz 260...