Genetic algorithm for accurate modeling of distributed Bragg reflector laser power and wavelength

Wei Quan; Xinyi Li; Jiali Liu; Kesheng Shen; Yueyang Zhai

doi:10.1117/1.OE.58.2.026108

Genetic algorithm for accurate modeling of distributed Bragg reflector laser power and wavelength

Wei Quan
, Xinyi Li
, Jiali Liu
, Kesheng Shen
, Yueyang Zhai^*

^*Corresponding author for this work

School of Instrumentation and Optoelectronic Engineering

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

We propose a modeling methodology tailored to predicting the wavelength and power output from a distributed Bragg reflector laser for use in quantum measurements. The relationship between power, wavelength, current, and temperature is acquired with a genetic algorithm (GA). The function set and termination set for GA are determined from the physical mechanisms of laser current, temperature, and output performance. To verify the validity of the method, measured data are divided into a training group and a test group. The test results show that our models can accurately predict the value of power and wavelength at the given current and temperature, with the RMSE of 13.4 μW and 6.0 × 10^{× 5} nm, respectively. This method can help enhance the output performance of a laser.

Original language	English
Article number	026108
Journal	Optical Engineering
Volume	58
Issue number	2
DOIs	https://doi.org/10.1117/1.OE.58.2.026108
State	Published - 1 Feb 2019

Keywords

diode lasers
genetic algorithm
laser stabilization
lasers frequency
lasers tuning

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10.1117/1.OE.58.2.026108

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title = "Genetic algorithm for accurate modeling of distributed Bragg reflector laser power and wavelength",

abstract = "We propose a modeling methodology tailored to predicting the wavelength and power output from a distributed Bragg reflector laser for use in quantum measurements. The relationship between power, wavelength, current, and temperature is acquired with a genetic algorithm (GA). The function set and termination set for GA are determined from the physical mechanisms of laser current, temperature, and output performance. To verify the validity of the method, measured data are divided into a training group and a test group. The test results show that our models can accurately predict the value of power and wavelength at the given current and temperature, with the RMSE of 13.4 μW and 6.0 × 10× 5 nm, respectively. This method can help enhance the output performance of a laser.",

keywords = "diode lasers, genetic algorithm, laser stabilization, lasers frequency, lasers tuning",

author = "Wei Quan and Xinyi Li and Jiali Liu and Kesheng Shen and Yueyang Zhai",

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doi = "10.1117/1.OE.58.2.026108",

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T1 - Genetic algorithm for accurate modeling of distributed Bragg reflector laser power and wavelength

AU - Quan, Wei

AU - Li, Xinyi

AU - Liu, Jiali

AU - Shen, Kesheng

AU - Zhai, Yueyang

PY - 2019/2/1

Y1 - 2019/2/1

N2 - We propose a modeling methodology tailored to predicting the wavelength and power output from a distributed Bragg reflector laser for use in quantum measurements. The relationship between power, wavelength, current, and temperature is acquired with a genetic algorithm (GA). The function set and termination set for GA are determined from the physical mechanisms of laser current, temperature, and output performance. To verify the validity of the method, measured data are divided into a training group and a test group. The test results show that our models can accurately predict the value of power and wavelength at the given current and temperature, with the RMSE of 13.4 μW and 6.0 × 10× 5 nm, respectively. This method can help enhance the output performance of a laser.

AB - We propose a modeling methodology tailored to predicting the wavelength and power output from a distributed Bragg reflector laser for use in quantum measurements. The relationship between power, wavelength, current, and temperature is acquired with a genetic algorithm (GA). The function set and termination set for GA are determined from the physical mechanisms of laser current, temperature, and output performance. To verify the validity of the method, measured data are divided into a training group and a test group. The test results show that our models can accurately predict the value of power and wavelength at the given current and temperature, with the RMSE of 13.4 μW and 6.0 × 10× 5 nm, respectively. This method can help enhance the output performance of a laser.

KW - diode lasers

KW - genetic algorithm

KW - laser stabilization

KW - lasers frequency

KW - lasers tuning

UR - https://www.scopus.com/pages/publications/85062616523

U2 - 10.1117/1.OE.58.2.026108

DO - 10.1117/1.OE.58.2.026108

M3 - 文章

AN - SCOPUS:85062616523

SN - 0091-3286

VL - 58

JO - Optical Engineering

JF - Optical Engineering

IS - 2

M1 - 026108

ER -

Genetic algorithm for accurate modeling of distributed Bragg reflector laser power and wavelength

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Keywords

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