Wavelength = speed /frequency = 332/440 = 75.45 cm(rounded)
Lower frequency equates to a longer wavelength, so the 340 Hz tuning fork would emit a longer wavelength sound.
A tuning fork combined with a quartz sound magnet.
The frequency of a wave motion is the number of waves passing through a fixed position each second. Thus, the sound wave emitted from the tuning fork has a frequency of 384 Hz means that the fork is vibrating 384 times per second.
standard tuning
The wavelength (λ) times the frequency (f) is equal to the velocity. The speed of sound in air is roughly 340 meters per second. That number obviously depends on the temperature of the air, the percentage of humidity, and many other things. If λf=v, then with some basic pre-pre-pre-algebra we can determine that λ=v/f. So, time to plug in numbers. λ = 340/440. λ = .7727 meters, or more precisely, 17/22
Lower frequency equates to a longer wavelength, so the 340 Hz tuning fork would emit a longer wavelength sound.
The wavelength of the tuning note A440 can be found using the formula: wavelength = speed of sound / frequency. The period can be calculated using the formula: period = 1 / frequency. For A440 (440 Hz), frequency is 440 Hz, speed of sound is approximately 343 m/s, so the wavelength is around 0.779 meters and the period is approximately 0.00227 seconds.
If it's vibrating in air, then the wavelength of the sound it produces is(343) divided by (the tuning fork's frequency) meters
A tuning fork combined with a quartz sound magnet.
The wavelength of sonar waves can vary depending on the frequency of the sound waves being emitted. In general, the wavelength of sonar used in underwater applications ranges from a few centimeters to several meters. The selection of the frequency and corresponding wavelength is based on the specific requirements of the sonar system and the properties of the underwater environment being explored.
3.8 mm = 0.0038 meter(340 meters per second) / (0.0038 meter) = 89,474 per second = 89,474 Hz. (rounded)
The frequency of a wave motion is the number of waves passing through a fixed position each second. Thus, the sound wave emitted from the tuning fork has a frequency of 384 Hz means that the fork is vibrating 384 times per second.
The loudness of a sound is typically measured in terms of intensity or amplitude, not wavelength. The wavelength of a sound wave affects its pitch, not its loudness. Sound intensity is related to the amount of energy carried by the sound wave.
standard tuning
When the sound source moves away from you, the pitch perceived by your ears decreases. This is because the sound waves from the moving source are stretched out, resulting in a longer wavelength and a lower frequency.
The wavelength (λ) times the frequency (f) is equal to the velocity. The speed of sound in air is roughly 340 meters per second. That number obviously depends on the temperature of the air, the percentage of humidity, and many other things. If λf=v, then with some basic pre-pre-pre-algebra we can determine that λ=v/f. So, time to plug in numbers. λ = 340/440. λ = .7727 meters, or more precisely, 17/22
A higher pitched sound has a shorter wavelength than a lower pitched sound.