Hermann von Helmholtz built sets of tuned brass spheres in the 1860s, each with a small neck to insert in the ear and a nipple opposite. Held to the ear, a sphere would ring loudly only when the surrounding sound contained its resonant frequency — a mechanical spectrum analyser. With them Helmholtz picked apart the overtones (“partials”) of vowels and instruments one by one, establishing that timbre is the pattern of a tone’s harmonics. The resonators, described in On the Sensations of Tone (1863), gave the frequency his name is now attached to, and the experiments seeded the whole idea — central to What is hearing? — that the ear performs a running Fourier analysis of sound. The cochlea, it turned out, is a bank of exactly such resonators, graded along its length.
11.3 The Helmholtz resonator
Blow across the mouth of a bottle and it sounds a single, definite pitch — far below any pitch the bottle’s small size would suggest from a standing wave. The bottle is a Helmholtz resonator: a cavity of compliant air with a narrow open neck of massive air, wired in series. It is the acoustic mass-on-a-spring, and it is the single most useful lumped circuit in the ear and its instruments. This lesson derives its frequency, its damping, and why it rings where it does.
The mass, the spring, and the frequency
From 11.1: the neck is an inertance , the cavity a compliance . Air pushed into the neck accelerates (mass), compresses the cavity (spring), which pushes back — the two exchange energy at the resonance of their series combination, (11.2).
▶ Helmholtz frequency ω₀ = c√(S / V ℓ') Derivation
Substitute the two elements into :
The equilibrium density cancels — the resonance depends only on the geometry and the speed of sound. In ordinary frequency,
The trend is worth committing to intuition: a bigger cavity (softer spring) or a longer neck (more mass) lowers the pitch; a wider neck raises it (a stiffer coupling — more area pushing on the spring outweighs the extra mass). This is why a nearly empty bottle (large ) hums low and fills to a higher pitch as you pour.
The neck length in the formula is not quite the geometric length. The air just beyond each opening is dragged into the oscillation too, so the plug is effectively longer. The correction is about per open end (radius ) for a flanged opening, giving an effective length
For a short neck the correction can rival itself, so it is never optional in a real calculation.
- Helmholtz resonance frequency Hz
- neck cross-sectional area m^2
- cavity volume m^3
- effective neck length (geometric length + end corrections) m
- neck radius m
Bigger cavity or longer neck → lower pitch (more spring, more mass); wider neck → higher pitch. This is a mass-on-a-spring: the neck air is the mass, the cavity air the spring.
The schematic is a literal mass-on-a-spring: the neck air is the plug that moves, the cavity air the spring it compresses. Drag the three geometry sliders and watch track — larger or down, larger up.
Why it is a sharp, low pitch
Two features distinguish the Helmholtz resonance from an ordinary tube mode:
- It is far below the tube’s standing-wave frequencies. The lowest quarter-wave mode of the neck alone would sit near ; the Helmholtz mode is lower by a factor — set by the large cavity volume, not the small neck. A pop bottle resonates near 200 Hz though it is only ~20 cm tall (whose quarter-wave mode is ~400 Hz for the whole bottle, and much higher for the neck). The cavity’s compliance drags the pitch down.
- It is lightly damped, so it rings. Because the only losses are the small viscous and radiation resistances of 11.1, the resonator has a high quality factor (Chapter 2.5) — a narrow, selective response. This is exactly the driven, damped oscillator of Foundations 5.3: mass , spring , damping , and a driving pressure. Everything proven there about resonance width, phase, and transfers verbatim.
Where it appears
The Helmholtz resonator is not a curiosity; it is a recurring building block:
- The ear canal and concha add Helmholtz-like resonances to the ear’s response, part of what shapes the head-related transfer function.
- Vents and ports in earmoulds and hearing aids are deliberate necks onto the residual-ear-canal cavity; their Helmholtz resonance places a peak (and the vent’s inertance a low-frequency roll-off) exactly where the fitter wants it.
- Bass reflex loudspeakers, car “boom”, the ocarina, and acoustic wall absorbers are all tuned Helmholtz resonators.
- Even the middle-ear cavity behind the eardrum acts as a compliance that, with the ossicular mass, contributes a resonance to the transfer of sound to the cochlea (11.4).
The history — Helmholtz's brass spheres and the analysis of tone
The final lesson assembles compliances, inertances, and a resonator like this one into the small acoustic network that is the outer and middle ear.