Speckle classification of a multimode fiber based on
Inception V3

Zifei Li; Leihong Zhang; Leihong Zhang; Zili Zhang; Runchu Xu; Dawei Zhang

doi:10.1364/AO.463764

Applied Optics
Vol. 61,
Issue 29,
pp. 8850-8858
(2022)
•https://doi.org/10.1364/AO.463764

Speckle classification of a multimode fiber based on Inception V3

Zifei Li, Leihong Zhang, Zili Zhang, Runchu Xu, and Dawei Zhang

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Zifei Li, Leihong Zhang, Zili Zhang, Runchu Xu, and Dawei Zhang, "Speckle classification of a multimode fiber based on Inception V3," Appl. Opt. 61, 8850-8858 (2022)

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Related Topics
Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: May 13, 2022
- Revised Manuscript: September 19, 2022
- Manuscript Accepted: September 21, 2022
- Published: October 7, 2022

Abstract

Multimode optical fiber plays an important role in endoscope miniaturization. With the development of deep learning and machine learning, neural networks can be used to identify and classify speckle patterns obtained at the fiber output. Based on the speckle pattern of a HERLEV dataset cell image transmitted by a multimode fiber, this paper studies the recognition accuracy of various types of speckle by a support vector machine, K-nearest neighbor, and convolutional neural network (Inception V3). Meanwhile, we propose an image classification optimization algorithm based on improved Inception V3. The experimental results show that the improved algorithm model is better than the traditional machine learning method; the accuracy rate is 97.92%, which effectively improves the performance of the pathological cell diagnosis deep learning model and lays a theoretical and practical foundation for further clinical application.

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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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Environment Category	Project	Illustrate
Hardware	CPU	Xeon e5-2640
environment	GPU	Nvidia GeForce 3090
	RAM	64 GB
	Hard disk	256 GB
Software	Operating system	Ubuntu
environment	Operating system	Python3.8
	Deep learning framework	Tensorflow2.0

Layer (Type)	Output Shape	Param#
Input	(None,256,256,1)	0
Inception_V3(Functional)	(None,6,6,2048)	21802784
Dropout	(None,6,6,2048)	0
Batch_normalization	(None,6,6,1024)	8192
Conv2d	(None,6,6,1024)	18875392
Conv2d_1	(None,6,6,1024)	9438208
Max_pooling2d	(None,3,3,1024)	0
Dropout	(None,3,3,1024)	0
Batch_normalization	(None,3,3,1024)	4096
Flatten	(None,9216)	0
Dense	(None,1024)	9438208
Dense	(None,7)	7175

	Predict Result
Reality	True	False
True	TP	FN
False	FP	TN

Model	Accuracy	F1-Score	Train Time	Test Time
SVM	95.52%	0.803	88.3 s	0.06 s
KNN	96.97%	0.905	46.8 s	0.02 s
Proposed model	97.92%	0.945	250.9 s	3.32 s

Number of Categories	2	3	4	5	6	7
SVM	99.33%	97.68%	96.76%	95.33%	95.62%	95.52%
KNN	98.66%	98.84%	98.30%	97.77%	97.38%	96.97%
Proposed model	98.59%	98.22%	98.17%	98.11%	97.67%	97.92%

Number of Training Samples	200	500	1000	2000	3500	4000	6000	8253
SVM	75.42%	76.45%	83.41%	93.45%	94.41%	94.45%	94.69%	95.52%
KNN	73.61%	77.69%	82.61%	92.69%	93.51%	93.83%	95.23%	96.85%
Proposed model	61.34%	71.78%	82.59%	92.76%	94.76%	95.92%	97.31%	97.92%

Fiber Length	6 cm	12 cm	18 cm	24 cm
SVM	95.52%	72.15%	81.29%	65.81%
KNN	96.97%	90.23%	82.61%	76.45%
Proposed model	97.92%	96.58%	97.6%	93.83%

Abstract

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Applied Optics