Revision as of 18:28, 12 May 2024 edit InternetArchiveBot (talk \| contribs) Bots, Pending changes reviewers 5,672,041 edits Rescuing 1 sources and tagging 0 as dead.) #IABot (v2.0.9.5) (Whoop whoop pull up - 19461 ← Previous edit		Revision as of 04:40, 28 December 2024 edit undo 186.169.134.10 (talk) →Initial instability and gain Next edit →
Line 80: Modulation instability only happens under certain circumstances. The most important condition is ''anomalous group velocity [[dispersion relation\|dispersion]]'', whereby pulses with shorter [[wavelength]]s travel with higher [[group velocity]] than pulses with longer wavelength.<ref name="agrawal" /> (This condition assumes a ''focusing'' [[Kerr nonlinearity]], whereby refractive index increases with optical intensity.)<ref name="agrawal" /> The instability is strongly dependent on the frequency of the perturbation. At certain frequencies, a perturbation will have little effect, ~~whilst~~while at other frequencies, a perturbation will [[exponential growth\|grow exponentially]]. The overall [[Gain (electronics)\|gain]] spectrum can be derived [[Analytical expression\|analytically]], as is shown below. Random perturbations will generally contain a broad range of frequency components, and so will cause the generation of spectral sidebands which reflect the underlying gain spectrum. The tendency of a perturbing signal to grow makes modulation instability a form of [[amplifier\|amplification]]. By tuning an input signal to a peak of the gain spectrum, it is possible to create an [[optical amplifier]].

Modulational instability: Difference between revisions