Beat (acoustics)

Diagram of beat frequency

In acoustics, a beat is an interference pattern between two sounds of slightly different frequencies, perceived as a periodic variation in volume whose rate is the difference of the two frequencies.

With tuning instruments that can produce sustained tones, beats can be readily recognized. Tuning two tones to a unison will present a peculiar effect: when the two tones are close in pitch but not identical, the difference in frequency generates the beating. The volume varies like in a tremolo as the sounds alternately interfere constructively and destructively. As the two tones gradually approach unison, the beating slows down and may become so slow as to be imperceptible. As the two tones get further apart, their beat frequency starts to approach the range of human pitch perception,^[1] the beating starts to sound like a note, and a combination tone is produced. This combination tone can also be referred to as a missing fundamental, as the beat frequency of any two tones is equivalent to the frequency of their implied fundamental frequency.

Mathematics and physics of beat tones[]

The sum (blue) of two sine waves (red, green) is shown as one of the waves increases in frequency. The two waves are initially identical, then the frequency of the green wave is gradually increased by 25%. Constructive and destructive interference can be seen.

This phenomenon is best known in acoustics or music, though it can be found in any linear system: "According to the law of superposition, two tones sounding simultaneously are superimposed in a very simple way: one adds their amplitudes".^[2] If a graph is drawn to show the function corresponding to the total sound of two strings, it can be seen that maxima and minima are no longer constant as when a pure note is played, but change over time: when the two waves are nearly 180 degrees out of phase the maxima of one wave cancel the minima of the other, whereas when they are nearly in phase their maxima sum up, raising the perceived volume.

It can be proven with the help of a sum-to-product trigonometric identity (see List of trigonometric identities) that the envelope of the maxima and minima form a wave whose frequency is half the difference between the frequencies of the two original waves. Consider two sine waves of unit amplitude:^[3]

{\cos(2\pi f_{1}t)+\cos(2\pi f_{2}t)}={2\cos \left(2\pi {\frac {f_{1}+f_{2}}{2}}t\right)\cos \left(2\pi {\frac {f_{1}-f_{2}}{2}}t\right)}

If the two original frequencies are quite close (for example, a difference of approximately twelve hertz),^[4] the frequency of the cosine of the right side of the expression above, that is f₁ − f₂/2, is often too low to be perceived as an audible tone or pitch. Instead, it is perceived as a periodic variation in the amplitude of the first term in the expression above. It can be said that the lower frequency cosine term is an envelope for the higher frequency one, i.e. that its amplitude is modulated. The frequency of the modulation is f₁ + f₂/2, that is, the average of the two frequencies. It can be noted that every second burst in the modulation pattern is inverted. Each peak is replaced by a trough and vice versa. However, because the human ear is not sensitive to the phase of a sound, only its amplitude or intensity, only the magnitude of the envelope is heard. Therefore, subjectively, the frequency of the envelope seems to have twice the frequency of the modulating cosine, which means the audible beat frequency is:^[5]

f_{\text{beat}}=f_{1}-f_{2}\,

This can be seen on the adjacent diagram.

A 110 Hz A sine wave (magenta; first 2 seconds), a 104 Hz G♯ sine wave (cyan; following 2 seconds), their sum (blue; final 2 seconds) and the corresponding envelope (red)

A physical interpretation is that when

\cos \left(2\pi {\frac {f_{1}-f_{2}}{2}}t\right)=1

the two waves are in phase and they interfere constructively. When it is zero, they are out of phase and interfere destructively. Beats occur also in more complex sounds, or in sounds of different volumes, though calculating them mathematically is not so easy.^{[original research?]}

For a human ear to hear beat phenomena, the ratio of frequencies should be less than ${\frac {7}{6}}$ or else the brain perceives them as two different frequencies^{[citation needed]}.

Beating can also be heard between notes that are near to, but not exactly, a harmonic interval, due to some harmonic of the first note beating with a harmonic of the second note. For example, in the case of perfect fifth, the third harmonic (i.e. second overtone) of the bass note beats with the second harmonic (first overtone) of the other note. As well as with out-of tune notes, this can also happen with some correctly tuned equal temperament intervals, because of the differences between them and the corresponding just intonation intervals:^{[citation needed]} see Harmonic series (music)#Harmonics and tuning.

Binaural beats[]

Binaural beats

To experience the binaural beats perception, it is best to listen to this file with headphones on moderate to weak volume – the sound should be easily heard, but not loud. Note that the sound appears to pulsate only when heard through both earphones. Time duration of 10 seconds

Binaural Beats Base tone 200 Hz, beat frequency from 7 Hz to 12.9 Hz. Time duration of 9 minutes.

A binaural beat is an auditory illusion perceived when two different pure-tone sine waves, both with frequencies lower than 1500 Hz, with less than a 40 Hz difference between them, are presented to a listener dichotically (one through each ear).

For example, if a 530 Hz pure tone is presented to a subject's right ear, while a 520 Hz pure tone is presented to the subject's left ear, the listener will perceive the auditory illusion of a third tone, in addition to the two pure-tones presented to each ear. The third sound is called a binaural beat, and in this example would have a perceived pitch correlating to a frequency of 10 Hz, that being the difference between the 530 Hz and 520 Hz pure tones presented to each ear.^{[citation needed]}

Binaural-beat perception originates in the inferior colliculus of the midbrain and the superior olivary complex of the brainstem, where auditory signals from each ear are integrated and precipitate electrical impulses along neural pathways through the reticular formation up the midbrain to the thalamus, auditory cortex, and other cortical regions.^[6]

Some claimed benefits of binaural beats therapy may include: reduced stress, reduced anxiety, increased focus, increased concentration, increased motivation, increased confidence, and deeper meditation. However, there is no evidence supporting the beneficial claims of those promoting the supposed benefits.^[7] As research is inconclusive about the clinical benefits of binaural beat therapy, it is best not to replace traditional treatments for stress and anxiety with this type of intervention until conclusive evidence is presented. As of 2020, binaural beat therapy was not part of standard care for any condition in the United Kingdom.^[8]

There are no known side effects to listening to binaural beats, although lengthy exposure to sounds at or above 85 decibels can cause hearing loss over time. This is roughly the level of noise produced by heavy traffic.^[9]

Uses[]

Musicians commonly use interference beats objectively to check tuning at the unison, perfect fifth, or other simple harmonic intervals.^[10] Piano and organ tuners even use a method involving counting beats, aiming at a particular number for a specific interval.

The composer Alvin Lucier has written many pieces that feature interference beats as their main focus. Italian composer Giacinto Scelsi, whose style is grounded on microtonal oscillations of unisons, extensively explored the textural effects of interference beats, particularly in his late works such as the violin solos Xnoybis (1964) and L'âme ailée / L'âme ouverte (1973), which feature them prominently (note that Scelsi treated and notated each string of the instrument as a separate part, so that his violin solos are effectively quartets of one-strings, where different strings of the violin may be simultaneously playing the same note with microtonal shifts, so that the interference patterns are generated). Composer Phill Niblock's music is entirely based on beating caused by microtonal differences.^{[citation needed]}

Sample[]

Beating waveforms (high frequency)

220 Hz A₃ (left channel) and 207.65 Hz G♯₃ (right channel) beating at 12.35 Hz

Problems playing this file? See media help.

Beating waveforms (low frequency)

220 Hz A₃ and 222 Hz tone beating at 2 Hz

Problems playing this file? See media help.

References[]

^ Levitin, Daniel J. (2006). This is Your Brain on Music: The Science of a Human Obsession. Dutton. p. 22. ISBN 978-0525949695.
^ Winckel, Fritz (1967). Music, Sound and Sensation: A Modern Exposition, p. 134. Courier. ISBN 978-0486165820.
^ "Interference beats and Tartini tones", Physclips, UNSW.edu.au.
^ "Acoustics FAQ", UNSW.edu.au.
^ Roberts, Gareth E. (2016). From Music to Mathematics: Exploring the Connections, p. 112. JHU. ISBN 978-1421419190.
^ Oster, G (October 1973). "Auditory beats in the brain". Scientific American. 229 (4): 94–102. Bibcode:1973SciAm.229d..94O. doi:10.1038/scientificamerican1073-94. PMID 4727697.
^ Dunning, Brian (March 31, 2009). "Skeptoid #147: Binaural Beats: Not Digital Drugs". Skeptoid. Retrieved October 25, 2020.
^ Smith, Lori; Gonzales, Andrew (September 30, 2019). "What are binaural beats and how do they work?". Medical News Today. Brighton, UK: Healthline Media UK Ltd. Retrieved October 25, 2020.
^ "Binaural Beats: Sleep, Therapy, and Meditation". Healthline. 2017-10-06. Retrieved 2021-07-20.
^ Campbell, Murray; Greated, Clive A.; and Myers, Arnold (2004). Musical Instruments: History, Technology, and Performance of Instruments of Western Music, p. 26. Oxford. ISBN 978-0198165040. "Listening for beats can be a useful method of tuning a unison, for example between two strings on a lute,..."

External links[]

[1] Levitin, Daniel J. (2006). This is Your Brain on Music: The Science of a Human Obsession. Dutton. p. 22. ISBN 978-0525949695.

[2] Winckel, Fritz (1967). Music, Sound and Sensation: A Modern Exposition, p. 134. Courier. ISBN 978-0486165820.

[3] "Interference beats and Tartini tones", Physclips, UNSW.edu.au.

[4] "Acoustics FAQ", UNSW.edu.au.

[5] Roberts, Gareth E. (2016). From Music to Mathematics: Exploring the Connections, p. 112. JHU. ISBN 978-1421419190.

[oster-6] Oster, G (October 1973). "Auditory beats in the brain". Scientific American. 229 (4): 94–102. Bibcode:1973SciAm.229d..94O. doi:10.1038/scientificamerican1073-94. PMID 4727697.

[7] Dunning, Brian (March 31, 2009). "Skeptoid #147: Binaural Beats: Not Digital Drugs". Skeptoid. Retrieved October 25, 2020.

[MedicalNewsToday-8] Smith, Lori; Gonzales, Andrew (September 30, 2019). "What are binaural beats and how do they work?". Medical News Today. Brighton, UK: Healthline Media UK Ltd. Retrieved October 25, 2020.

[9] "Binaural Beats: Sleep, Therapy, and Meditation". Healthline. 2017-10-06. Retrieved 2021-07-20.

[10] Campbell, Murray; Greated, Clive A.; and Myers, Arnold (2004). Musical Instruments: History, Technology, and Performance of Instruments of Western Music, p. 26. Oxford. ISBN 978-0198165040. "Listening for beats can be a useful method of tuning a unison, for example between two strings on a lute,..."

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show v t Acoustics
Acoustical engineering	Architectural acoustics Monochord Reverberation Soundproofing String vibration String resonance	Spectrogram
Psychoacoustics	Bark scale Combination tone Equal-loudness contour Fletcher–Munson curves Mel scale Missing fundamental
Frequency and pitch	Beat Formant Fundamental frequency Frequency spectrum harmonic spectrum Harmonic Series Inharmonicity Mersenne's laws Overtone Resonance Standing wave Node Subharmonic
Acousticians	John Backus Jens Blauert Ernst Chladni Hermann von Helmholtz Carleen Hutchins Franz Melde Marin Mersenne Werner Meyer-Eppler Lord Rayleigh Joseph Sauveur D. Van Holliday Thomas Young
Related topics	Echo Infrasound Sound Ultrasound Musical acoustics Piano Violin
Category

show v Consonance and dissonance
Argument Avoid note Beating Cadence Chord Interval Nonchord tone Cambiata Changing tones Pedal point Preparation Resolution Musical note Spectra
Consonances	Unison Minor third Major third Perfect fourth Perfect fifth Minor sixth Major sixth Octave
Dissonances	Minor second Major second Tritone Minor seventh Major seventh
List of musical intervals

show v t Frequency and pitch
Notation	Concert pitch A440 Enharmonic Helmholtz pitch notation Letter notation Piano key frequencies Pitch class Scientific pitch notation
Perception	Absolute pitch Ear training Pitch circularity Relative pitch Tonal memory Tone deafness Virtual pitch
See also	Electronic tuner Mersenne's laws Microtuner Musical tuning Beating Pitch pipe Savart wheel Tuning fork