Stochastic collocation for device-level variability analysis in integrated photonics

Yufei Xing; Domenico Spina; Ang Li; Tom Dhaene; Wim Bogaerts

doi:10.1364/prj.4.000093

Journals >Photonics Research >Volume 4 >Issue 2 >Page 0093 > Article

Photonics Research
Vol. 4, Issue 2, 0093 (2016)

Stochastic collocation for device-level variability analysis in integrated photonics

Yufei Xing¹, Domenico Spina², Ang Li¹, Tom Dhaene², and Wim Bogaerts^1、3、*

Author Affiliations

¹Photonics Research Group, Department of Information Technology, Center for Nano and Biophotonics, Ghent University imec, Ghent B-9000, Belgium

²Department of Information Technology, Internet Based Communication Networks and Services (IBCN), Ghent University iMinds, Gaston Crommenlaan 8 Bus 201, B-9050 Gent, Belgium

³Luceda Photonics, 9200 Dendermonde, Belgium

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DOI: 10.1364/prj.4.000093 Cite this Article Set citation alerts

Yufei Xing, Domenico Spina, Ang Li, Tom Dhaene, Wim Bogaerts. Stochastic collocation for device-level variability analysis in integrated photonics[J]. Photonics Research, 2016, 4(2): 0093 Copy Citation Text

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Abstract

We demonstrate the use of stochastic collocation to assess the performance of photonic devices under the effect of uncertainty. This approach combines high accuracy and efficiency in analyzing device variability with the ease of implementation of sampling-based methods. Its flexibility makes it suitable to be applied to a large range ofphotonic devices. We compare the stochastic collocation method with a Monte Carlo technique on a numerical analysis of the variability in silicon directional couplers.

Keywords

and statistics stochastic processes Integrated optics devices Probability theory Waveguides

Y (ξ) = \sum_{i = 1}^{Q} Y (ξ_{i}) L_{i} (ξ),

(1)

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L_{i} (ξ) = \prod_{i = 1, i \neq j}^{Q} \frac{ξ - ξ_{i}}{ξ_{j} - ξ_{i}},

(2)

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Y (ξ) = \sum_{i_{1} = 1}^{Q_{k_{1}}} \dots \sum_{i_{N} = 1}^{Q_{k_{N}}} Y (ξ_{i_{1}}^{k_{1}}, \dots, ξ_{i_{N}}^{k_{N}}) (L_{i_{1}}^{k_{1}} \otimes \dots \otimes L_{i_{N}}^{k_{N}}),

(3)

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Q = \prod_{n = 1}^{N} Q_{k_{n}} .

(4)

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μ (Y (ξ)) = \int_{Ω} Y (ξ) W (ξ) d ξ,

(5)

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μ (Y (ξ)) = \int_{Ω} \sum_{i = 1}^{Q} Y (ξ_{i}) L_{i} (ξ) W (ξ) d ξ,

(6)

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K (z) = \sin^{2} (κ z + κ_{0}) .

(7)

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κ = \frac{π}{λ} (n_{eff_o} - n_{eff_e}),

(8)

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W_{η} = \frac{1}{2 π \det {(C)}^{1 / 2}} \exp (- \frac{1}{2} {(η - μ)}^{T} C^{- 1} (η - μ)),

(9)

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η = μ + {VE}^{1 / 2} ξ,

(10)

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l_{3 dB} = \arcsin (sqrt (0.5)) / κ .

(11)

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Yufei Xing, Domenico Spina, Ang Li, Tom Dhaene, Wim Bogaerts. Stochastic collocation for device-level variability analysis in integrated photonics[J]. Photonics Research, 2016, 4(2): 0093

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