Design optimization and tolerance analysis of a spot-size converter for the taper-assisted vertical integration platform in InP

Valery Tolstikhin; Shayan Saeidi; Ksenia Dolgaleva

doi:10.1364/AO.57.003586

Applied Optics
Vol. 57,
Issue 13,
pp. 3586-3591
(2018)
•https://doi.org/10.1364/AO.57.003586

Design optimization and tolerance analysis of a spot-size converter for the taper-assisted vertical integration platform in InP

Valery Tolstikhin, Shayan Saeidi, and Ksenia Dolgaleva

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Valery Tolstikhin, Shayan Saeidi, and Ksenia Dolgaleva, "Design optimization and tolerance analysis of a spot-size converter for the taper-assisted vertical integration platform in InP," Appl. Opt. 57, 3586-3591 (2018)

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Abstract

We report on the design optimization and tolerance analysis of a multistep lateral-taper spot-size converter based on indium phosphide (InP), performed using the Monte Carlo method. Being a natural fit to (and a key building block of) the regrowth-free taper-assisted vertical integration platform, such a spot-size converter enables efficient and displacement-tolerant fiber coupling to InP-based photonic integrated circuits at a wavelength of 1.31 μm. An exemplary four-step lateral-taper design featuring 0.35 dB coupling loss at optimal alignment of a standard single-mode fiber; $\geq 7 μm$ 1 dB displacement tolerance in any direction in a facet plane; and great stability against manufacturing variances is demonstrated.

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Layer	Description	Thickness (μm)	$n_{1.31 μm}$
$2 N + 5$	InP AWG Separation	0.527	3.2026
$2 N + 4$	GaInAsP PWG Core	0.405	3.2565
$2 N + 3$	InP PWG Separation 2	0.232	3.2026
$2 N + 2$	GaInAsP Etch Stop	0.005	3.2140
$2 N + 1$	InP PWG Separation 1	0.254	3.2026
$2 N$	GaInAsP CWG Core $N$	0.032	3.2565
—	—	—	—
5	InP CWG Separation 2	$0.361 + 0.095 (N - 2)$	3.2026
4	GaInAsP CWG Core 2	0.032	3.2565
3	InP CWG Separation 1	$0.361 + 0.095 (N - 1)$	3.2026
2	GaInAsP CWG Core 1	0.032	3.2565
1	InP Buffer	0.3	3.2026
0	InP Substrate	Semi-infinite	3.2026

#	Parameter	Unit	Variance Range	Optimum Value
1	$n_{Q}$	u. d.	3.25–3.3	3.2565
2	$t_{CWG}$	μm	0.02–0.04	0.032
3	$s_{CWG, N - 1}$	μm	0.25–0.4	0.361
4	$Δ s_{CWG}$	μm	0–0.1	0.095
5	$s_{PWG, 1}$	μm	0.25–0.4	0.254
6	$s_{PWG, 2}$	μm	0.2–0.3	0.232
7	$t_{PWG}$	μm	0.4–0.5	0.405
8	$s_{AWG}$	μm	0.4–0.6	0.527
9	$w_{CWG}$	μm	12–16	15
10	$w_{TWG 1}$	μm	2.5–5	2.83
11	$w_{TWG 2}$	μm	1.5–2.5	2.347
12	$w_{PWG}$	μm	0.5–0.7	0.6

Layer	Description	Thickness (μm)	$n_{1.31 μm}$
$2 N + 5$	InP AWG Separation	0.527	3.2026
$2 N + 4$	GaInAsP PWG Core	0.405	3.2565
$2 N + 3$	InP PWG Separation 2	0.232	3.2026
$2 N + 2$	GaInAsP Etch Stop	0.005	3.2140
$2 N + 1$	InP PWG Separation 1	0.254	3.2026
$2 N$	GaInAsP CWG Core $N$	0.032	3.2565
—	—	—	—
5	InP CWG Separation 2	$0.361 + 0.095 (N - 2)$	3.2026
4	GaInAsP CWG Core 2	0.032	3.2565
3	InP CWG Separation 1	$0.361 + 0.095 (N - 1)$	3.2026
2	GaInAsP CWG Core 1	0.032	3.2565
1	InP Buffer	0.3	3.2026
0	InP Substrate	Semi-infinite	3.2026

#	Parameter	Unit	Variance Range	Optimum Value
1	$n_{Q}$	u. d.	3.25–3.3	3.2565
2	$t_{CWG}$	μm	0.02–0.04	0.032
3	$s_{CWG, N - 1}$	μm	0.25–0.4	0.361
4	$Δ s_{CWG}$	μm	0–0.1	0.095
5	$s_{PWG, 1}$	μm	0.25–0.4	0.254
6	$s_{PWG, 2}$	μm	0.2–0.3	0.232
7	$t_{PWG}$	μm	0.4–0.5	0.405
8	$s_{AWG}$	μm	0.4–0.6	0.527
9	$w_{CWG}$	μm	12–16	15
10	$w_{TWG 1}$	μm	2.5–5	2.83
11	$w_{TWG 2}$	μm	1.5–2.5	2.347
12	$w_{PWG}$	μm	0.5–0.7	0.6

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Applied Optics