Predicting instabilities of a tunable ring laser with an iterative map model

Brady Metherall; Brady Metherall; C. Sean Bohun; C. Sean Bohun

doi:10.1364/JOSAB.424346

Journal of the Optical Society of America B
Vol. 38,
Issue 9,
pp. 2479-2487
(2021)
•https://doi.org/10.1364/JOSAB.424346

Predicting instabilities of a tunable ring laser with an iterative map model

Brady Metherall and C. Sean Bohun

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Brady Metherall and C. Sean Bohun, "Predicting instabilities of a tunable ring laser with an iterative map model," J. Opt. Soc. Am. B 38, 2479-2487 (2021)

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Abstract

Simple mathematical models have been unable to predict the conditions leading to instabilities in a tunable ring laser. Here we propose a nonlinear iterative map model for tunable ring lasers. Solving a reduced nonlinear Schrödinger equation for each component in the laser cavity, we obtain an algebraic map for each component. Iterating through the maps gives the total effect of one round trip. By neglecting the nonlinearity, we find a linearly chirped Gaussian to be the analytic fixed point solution, which we analyze asymptotically. We then numerically solve the full nonlinear model, allowing us to probe the underlying interplay of dispersion, modulation, and nonlinearity as the pulse evolves over hundreds of round trips of the cavity. In the nonlinear case, we find that the chirp saturates and the Fourier transform of the pulse becomes more rectangular in shape. Finally, for a nominal plane in the parameter space, we uncover a rich, sharp boundary separating the stable region and the unstable region where instabilities degrade the pulse into an unsustainable state.

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Data Availability

Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Equations (51)

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Parameter	Description	Value	Units
$T_{M}$	Characteristic modulation time	15–150	ps
$β_{2} L_{D}$	Dispersion provided by the CFBG	10–2000	ps²
$γ$	Kerr nonlinearity coefficient	0.001–0.01	$W^{- 1} m^{- 1}$
$L_{f}$	Length of fiber between gain and optical coupler	0.15–1	m
$L_{g}$	Length of the Er-doped gain fiber	2–3	m
$α$	Loss of fiber due to scattering and absorption	$10^{- 4} - 0.3$	$m^{- 1}$
$R$	Reflectivity of optical coupler	0.1–0.9	–
$E_{s a t}$	Saturation energy of Er-doped gain fiber	$10^{3} - 10^{4}$	pJ
$g_{0}$	Small signal gain	1–10	$m^{- 1}$
$L_{T}$	Total length of fiber in the cavity	10–100	m

Parameter	Loss	Dispersion	Gain	Fiber
$α L$	$O (10^{- 1})$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{- 3})$
$L / L_{d i s p}$	$O (10^{- 3})$	$O (10^{- 1})$	$O (10^{- 3})$	$O (10^{- 3})$
$g_{0} L$	$O (10^{- 4})$	$O (10^{- 4})$	$O (10^{1})$	$O (10^{- 4})$
$L / L_{N L}$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{0})$

Parameter	Description	Value	Units
$T_{M}$	Characteristic modulation time	15–150	ps
$β_{2} L_{D}$	Dispersion provided by the CFBG	10–2000	ps²
$γ$	Kerr nonlinearity coefficient	0.001–0.01	$W^{- 1} m^{- 1}$
$L_{f}$	Length of fiber between gain and optical coupler	0.15–1	m
$L_{g}$	Length of the Er-doped gain fiber	2–3	m
$α$	Loss of fiber due to scattering and absorption	$10^{- 4} - 0.3$	$m^{- 1}$
$R$	Reflectivity of optical coupler	0.1–0.9	–
$E_{s a t}$	Saturation energy of Er-doped gain fiber	$10^{3} - 10^{4}$	pJ
$g_{0}$	Small signal gain	1–10	$m^{- 1}$
$L_{T}$	Total length of fiber in the cavity	10–100	m

Parameter	Loss	Dispersion	Gain	Fiber
$α L$	$O (10^{- 1})$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{- 3})$
$L / L_{d i s p}$	$O (10^{- 3})$	$O (10^{- 1})$	$O (10^{- 3})$	$O (10^{- 3})$
$g_{0} L$	$O (10^{- 4})$	$O (10^{- 4})$	$O (10^{1})$	$O (10^{- 4})$
$L / L_{N L}$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{- 3})$	$O (10^{0})$

Abstract

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Equations (51)

Journal of the Optical Society of America B