Analytical approximation for photonic array modes in 1D photonic crystal superlattices

Elena Smith; Vladislav Shteeman; Amos A. Hardy

doi:10.1364/AO.55.002819

Applied Optics
Vol. 55,
Issue 10,
pp. 2819-2826
(2016)
•https://doi.org/10.1364/AO.55.002819

Analytical approximation for photonic array modes in 1D photonic crystal superlattices

Elena Smith, Vladislav Shteeman, and Amos A. Hardy

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Elena Smith, Vladislav Shteeman, and Amos A. Hardy, "Analytical approximation for photonic array modes in 1D photonic crystal superlattices," Appl. Opt. 55, 2819-2826 (2016)

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Abstract

We present a comprehensive analytical approximation for array modes (both the modal fields and their associated propagation constants) for 1D photonic crystal superlattices (i.e., large periodic arrays of repeated sequences of different coupled waveguides/lasers). In this class, a regular periodicity of a photonic lattice is supplemented with the additional periodicity of a larger scale. Our approximation is a vectorial approach, accounting for the TE and TM polarizations. It can be applied to both the low- and high-contrast photonic devices. We used the model of standing waves for analytical evaluation of envelopes of array modes in a photonic superlattice. Combination of the model of standing waves with the coupled-mode formalism for infinite photonic superlattices allows evaluation of propagation constants of the array modes. Both the evaluations require only a fraction of a second for computation. Still, the results, acquired with the analytical approximation, are very close to those of well-established approaches. Furthermore, for the first time, analytical expressions for the modal fields and propagation constants become available.

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Waveguide Type	$n_{core}$	$n_{clad}$	Core Width, $a_{core}$ (μm)	Number of Guided Modes	Propagation Constant of the 1st Guided Mode, $β_{1}$ ( ${μm}^{- 1}$ )	Propagation Constant of the 2nd Guided Mode, $β_{2}$ ( ${μm}^{- 1}$ )
1	1.54	1.5	4.6	2	6.1939	6.104
2	1.525	1.5	4.2	1	6.1407	—
3	1.52	1.5	4.2	1	6.1253	—

Number of Supercells, $N$	Number of Waveguides in a Supercell, $S$	Single Site Width (μm)	Supercell Width, $Λ_{SC}$ (μm)	Number of Guided Modes in a Supercell, $G_{SC}$
14	3	5	15	4

	Cumulative Error
	Standard CMT	Analytical Approximation
1st band	$6 \times 10^{- 11}$	$2 \times 10^{- 9}$
2nd band	$10^{- 9}$	$9 \times 10^{- 10}$
3rd band	$7 \times 10^{- 9}$	$3 \times 10^{- 9}$
4th band	$10^{- 6}$	$10^{- 6}$

Cumulative Error
1st Array Mode of the 1st Band		1st Array Mode of the 3rd Band
Standard CMT	Analytical Approximation	Standard CMT	Analytical Approximation
$10^{- 6}$	$10^{- 2}$	$4 \times 10^{- 4}$	$2 \times 10^{- 2}$

Computation Method	Standard CMT		Analytical Approximation			Helmholtz Equation (Solution in Finite Differences)
Photonic Array	Propagation Constants and Envelopes $(s)$	Full Array Modes $(s)$	Propagation Constants $(s)$	Envelopes $(s)$	Full Array Modes $(s)$	Full Array Modes
Array of 100 parabolic waveguides, combined in 50 supercells; each waveguide supports 10 guided modes	25	60	$< 0.1$	$< 0.1$	35	2 h 20 min
Array of 240 parabolic waveguides, combined in 80 supercells; each waveguide supports 10 guided modes	330	540	$< 0.1$	$< 0.1$	210	not available

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Applied Optics