Calculate beat frequency from two interfering waves. Visualize amplitude modulation, cents difference, and musical interval analysis.
When two waves of slightly different frequencies overlap, they produce a phenomenon called "beating" — a periodic variation in amplitude at a frequency equal to the difference between the two original frequencies. This is the pulsing "wah-wah" sound you hear when two guitar strings are nearly but not exactly in tune.
The beat frequency formula is deceptively simple: f_beat = |f₁ − f₂|. Two waves at 440 Hz and 444 Hz produce 4 beats per second. Piano tuners use this effect to precisely tune strings by adjusting until the beats slow to zero (perfect unison). The same principle applies in radio (heterodyne receivers), music production (binaural beats), and physics (Doppler measurements).
This calculator computes the beat frequency, period, musical interval, and cents difference between any two frequencies. It visualizes the resulting amplitude-modulated waveform and provides a reference table of musical note frequencies for tuning applications. Check the example with realistic values before reporting.
Beat frequency analysis is used in tuning instruments, calibrating oscillators, measuring Doppler shifts, and designing audio effects. While the basic formula is simple, understanding the relationship between beat rate, musical cents, amplitude modulation, and waveform shape requires visualization.
This calculator provides all of these in one tool — the beat frequency, musical interval, cents difference, modulation depth, and a waveform display. It is useful for musicians, audio engineers, physics students, and anyone working with wave interference phenomena.
f_beat = |f₁ − f₂|. Period = 1/f_beat. Combined wave: y(t) = A₁sin(2πf₁t) + A₂sin(2πf₂t) = 2A·cos(2π·f_beat/2·t)·sin(2π·f_avg·t) for equal amplitudes. Cents = 1200 × log₂(f₂/f₁).
Result: 4 Hz beat frequency
Two waves at 440 Hz and 444 Hz produce 4 beats per second (4 Hz). The combined wave has a carrier frequency of 442 Hz with amplitude that varies from 0 to 2 at 4 Hz. The frequencies are 15.7 cents apart.
When two sinusoidal waves with frequencies f₁ and f₂ and equal amplitude A are superimposed, the result can be expressed as: y(t) = 2A·cos(π(f₁−f₂)t)·sin(π(f₁+f₂)t). This is a wave at the average frequency (f₁+f₂)/2 whose amplitude is modulated by a cosine function at half the beat frequency. The perceived beat rate is (f₁−f₂) because the amplitude envelope completes a full cycle (loud-quiet-loud) once per beat period.
For unequal amplitudes, the superposition still produces beats, but the amplitude never drops to zero. The modulation depth quantifies this: 100% modulation (equal amplitudes) means complete cancellation occurs, while lower modulation means the beats are less pronounced.
Piano tuners use beats to set temperament. Starting from a reference A4, they tune intervals by counting beats per second. In equal temperament, a perfect fifth should beat at predictable rates — for example, the A3-E4 fifth should produce about 1 beat per second. This is because equal temperament slightly narrows fifths from the pure 3:2 ratio.
In audio engineering, beat frequencies create effects like tremolo (amplitude modulation) and vibrato (frequency modulation). Ring modulators multiply two signals, producing sum and difference frequencies — a more extreme version of beating.
Heterodyne receivers in radio use the beat principle to convert high-frequency signals to an intermediate frequency (IF) that is easier to process. The local oscillator frequency is set so that the IF = |f_signal − f_LO| falls in the desired passband. Doppler radar uses the same principle: the beat between the transmitted and received signals reveals the target velocity from the frequency shift.
Beat frequency is the rate at which the amplitude of two superimposed waves oscillates. It equals the absolute difference between the two frequencies: f_beat = |f₁ − f₂|.
A tuner strikes two strings (or a string and a tuning fork) simultaneously. If they are slightly out of tune, beats are audible. The tuner adjusts the string until the beats slow to zero, indicating the frequencies match.
Binaural beats are perceived when different frequencies are played to each ear through headphones. The brain perceives a beat at the difference frequency. Claimed benefits for relaxation and focus are not strongly supported by research but are widely used.
When the beat frequency exceeds about 15-20 Hz, the brain can no longer resolve individual beats and instead perceives two separate tones. This is the limit of temporal resolution in human hearing.
Cents divide the octave into 1200 equal parts (100 cents per semitone). A difference of 1 cent is barely perceptible; trained musicians can detect differences of about 5-10 cents. 100 cents equals one semitone.
No — beat frequency depends only on the frequency difference. However, unequal amplitudes reduce the modulation depth: the beats do not fully cancel, so the amplitude varies between |A₁−A₂| and A₁+A₂ instead of 0 and 2A.