定义：
Free Spectral Range(FSR),波长为λ1和λ2的光照在标准具上，各自产生一组干涉圆环，若λ1的m级圆环和λ2的m-1级圆环重合.则把λ=λ1-λ2称为该标准具的自由光谱区（自由光谱范围）

波长为λ1和λ2的光照在标准具上，各自产生一组干涉圆环，若λ1的m级圆环和λ2的m-1级圆环重合.则把λ=λ1-λ2称为该标准具的自由光谱区（自由光谱范围）。
FSR一般用 表示。

一个腔体的FSR表达式为 ， 是腔体长度， 是腔内介质的群折射率， 是真空中的光速。

Definition: frequency spacing of the axial modes of an optical resonator

Alternative term: axial mode spacing

Formula symbol: Δν

Units: Hz

The free spectral range of an optical resonator (cavity) is the spacing of its axial (Gaussian-shaped) resonator modes in terms of optical frequency. It is also called axial mode spacing. For an empty standing-wave resonator of length L, it can be calculated as

For a ring resonator, the factor of 2 is removed, since there is no double pass.

For a standing-wave resonator filled with a dispersive medium, the free spectral range is determined by the group index, rather than by the ordinary refractive index:

This follows from the fact that the round-trip phase shift 2 k L = 2 L n ω/c must change by 2π from one resonance to the next one, and only through the group index one considers the full frequency dependence of the round-trip phase shift (including the frequency dependence of the refractive index). Due to chromatic dispersion, the group index can substantially deviate from the refractive index, and it generally is frequency-dependent.

For a waveguide resonator, one would have to calculate the group index using the frequency-dependent effective refractive index.

More generally, e.g. for an optical resonator containing different transparent media, the free spectral range is the inverse of the round-trip time (more precisely, the round-trip group delay) of a light pulse.

The free spectral range of a Fabry–Pérot interferometer (or a Lyot filter) often limits the optical frequency range in which it can be used as a spectrometer. A large free spectral range can thus be desirable. It can be obtained simply by making the resonator shorter – which, however, also leads to a larger bandwidth of the resonances, thus to poorer spectral resolution, as long as the same mirrors are used. For better resolution, one then needs to increase the finesse by minimizing the round-trip power losses of circulating light.

For a wavelength-tunable single-frequency laser, the free spectral range often (but not always) limits the achievable mode-hop-free tuning range.