1/T, where T=period in seconds.
frequency=wavespeed divided by wavelength.
TIME = 1/FREQUENCY T=1/F F=1/T F=1/(45.3) i dont think the number of waves matter, frequency is dependant on time, or angular frequency which is not given F=1/T F = 2pii/w
In a way, yes, as the pitch of a sound wave is determined by it's frequency f, and a waves period T is the reciprocal of f. i.e. T=1/f
To find the resonant frequency of a room, you can use a sound frequency generator and a microphone to measure the frequency at which sound waves resonate the most in the room. This frequency is the room's resonant frequency.
To find the frequency of diffracted waves, one can use the formula: f_d = (v_sound / λ_d) where: f_d is the frequency of the diffracted wave, v_sound is the speed of sound in the medium, and λ_d is the wavelength of the diffracted wave.
the frequency = 1/T where T is the time period of the wave so in this case T = 1/4 so f = 4 therefore the wave has a frequency of 4Hz
The frequency is 0.5 Hz. Since five waves pass in 10 seconds, you divide the number of waves by the time taken to find the frequency, which is five waves / 10 seconds = 0.5 Hz.
To find the time of a wave, you can use the formula T = 1/f, where T is the period of the wave and f is the frequency of the wave. The period is the time it takes for one complete cycle of the wave to pass a point. The frequency is the number of complete waves passing a point in a specific time period.
The number of circular revolutions made by the charged particle in one second. f=1/T unit of frequency is Hertz
Count the number of waves passing a point in one second. That is frequency. Or count waves for 10 seconds and divide by 10.
High frequency waves will have more energy than low-frequency waves. This is because energy is directly proportional to frequency in waves - the higher the frequency, the higher the energy.
For waves, frequency(f) is the inverse of period(T). Therefore, f = 1/T. f = 1/0.358s = 1.79cycles/s = 1.79Hz