Vibration reconstruction and optical feedback parameter evaluation based on the direction discrimination in self-mixing interferometry

Chol-Yong Ri; Jin-Hyok Choe; Hwa-Ryong Ri; Chol-Min Pak; Kyong-Rim Ri; Jin-Myong O

doi:10.1364/AO.421863

Applied Optics
Vol. 60,
Issue 13,
pp. 3801-3807
(2021)
•https://doi.org/10.1364/AO.421863

Vibration reconstruction and optical feedback parameter evaluation based on the direction discrimination in self-mixing interferometry

Chol-Yong Ri, Jin-Hyok Choe, Hwa-Ryong Ri, Chol-Min Pak, Kyong-Rim Ri, and Jin-Myong O

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Chol-Yong Ri, Jin-Hyok Choe, Hwa-Ryong Ri, Chol-Min Pak, Kyong-Rim Ri, and Jin-Myong O, "Vibration reconstruction and optical feedback parameter evaluation based on the direction discrimination in self-mixing interferometry," Appl. Opt. 60, 3801-3807 (2021)

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Related Topics
Table of Contents Category
- Lasers, Optical Amplifiers, and Laser Optics
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About this Article
History
- Original Manuscript: February 3, 2021
- Revised Manuscript: March 23, 2021
- Manuscript Accepted: April 1, 2021
- Published: April 26, 2021

Abstract

Laser diode-based self-mixing interferometry (SMI) is a promising technique for noncontact sensing and its industry. In this paper, a phase unwrapping method in the several optical feedback levels is proposed based on displacement direction. A novel, to the best of our knowledge, method for evaluating the optical feedback factor C simultaneously with the linewidth enhancement is proposed by taking into account the effect of the accuracy of the linewidth enhancement $ \alpha $ on the evaluated method for C based on the differential feature of vibration reconstruction signal. Simulations and experiments are conducted to verify the proposed method.

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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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No.	True $C$	True $α$	Estimated $C$	Estimated $α$	$C$ error
1	0.2	3.7	0.198	3.77	0.002
2	0.3	3.7	0.299	3.71	0.001
3	0.5	3.7	0.4995	3.7	0.0005
4	0.8	3.7	0.7997	3.77	0.0003
5	1	3.7	0.9998	3.7	0.0002
6	2	3.7	1.9996	3.69	0.0004
7	3	3.7	2.9997	3.7	0.0003
8	4	3.7	3.9996	3.7	0.0004
9	6	3.7	5.9994	3.7	0.0006

No.	True $C$	True $α$	Estimated $C$	Estimated $α$	$α$ error
1	3.2	3	3.1997	3.000	0
2	3.2	4	3.1993	3.99	0.01
3	3.2	5.6	3.1995	5.59	0.01
4	3.2	8.9	3.1995	8.87	0.03
5	3.2	12.9	3.1997	12.86	0.04

Parameter	Method in [26]	Proposed Method
$C$	1.770	1.848
$α$	5.686	5.214
$f_{0}$ (Hz)	58.0	58.07
$L_{0}$ (µm)	1.658	1.656

No.	True $C$	True $α$	Estimated $C$	Estimated $α$	$C$ error
1	0.2	3.7	0.198	3.77	0.002
2	0.3	3.7	0.299	3.71	0.001
3	0.5	3.7	0.4995	3.7	0.0005
4	0.8	3.7	0.7997	3.77	0.0003
5	1	3.7	0.9998	3.7	0.0002
6	2	3.7	1.9996	3.69	0.0004
7	3	3.7	2.9997	3.7	0.0003
8	4	3.7	3.9996	3.7	0.0004
9	6	3.7	5.9994	3.7	0.0006

No.	True $C$	True $α$	Estimated $C$	Estimated $α$	$α$ error
1	3.2	3	3.1997	3.000	0
2	3.2	4	3.1993	3.99	0.01
3	3.2	5.6	3.1995	5.59	0.01
4	3.2	8.9	3.1995	8.87	0.03
5	3.2	12.9	3.1997	12.86	0.04

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Applied Optics