Interpretability of Deep Learning Classification for Low-Carbon Steel Microstructures

被引：10

作者：

Maemura, Tatsuya ^{[1
]}

Terasaki, Hidenori ^{[1
]}

Tsutsui, Kazumasa ^{[2
]}

Uto, Kyohei ^{[1
]}

Hiramatsu, Shogo ^{[1
]}

Hayashi, Kotaro ^{[2
]}

Moriguchi, Koji ^{[2
]}

Morito, Shigekazu ^{[3
]}

机构：

[1] Kumamoto Univ, Fac Adv Sci & Technol, Kumamoto 8608555, Japan

[2] Nippon Steel Corp Ltd, Tech Res & Dev Bur, Futtsu 2938511, Japan

[3] Shimane Univ, Next Generat Tatara Cocreat Ctr, Matsue, Shimane 6908504, Japan

来源：

MATERIALS TRANSACTIONS | 2020年 / 61卷 / 08期

关键词：

low-carbon steel; martensite; bainite; scanning electron microscopy image; deep learning; local interpretable model-agnostic explanations; FEATURES;

D O I：

10.2320/matertrans.MT-M2020131

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

In this paper, a model is developed to identify the microstructure of low-carbon steel by deep learning. In classifying steel microstructures using a machine learning model, predictions are interpreted using local interpretable model-agnostic explanations (LIME) for the first time. The constructed model can accurately distinguish between eight microstructure types, including upper bainite, lower bainite, martensite, and their mixed structures. The model accuracy is 94.1% when individually predicted and 97.9% when predicted by majority vote. In addition, as a result of interpreting the predictions of the model by LIME, it is evident that the recognition criterion of the constructed model is partially consistent with the classic recognition criterion.

引用

页码：1584 / 1592

页数：9

共 50 条

[1] Classification of low-carbon pipe steel microstructures
M. A. Smirnov
I. Yu. Pyshmintsev
A. N. Boryakova
[J]. Metallurgist, 2010, 54 : 444 - 454
[2] CLASSIFICATION OF LOW-CARBON PIPE STEEL MICROSTRUCTURES
Smirnov, M. A.
Pyshmintsev, I. Yu.
Boryakova, A. N.
[J]. METALLURGIST, 2010, 54 (7-8) : 444 - 454
[3] DEVELOPMENT OF TEXTURES AND MICROSTRUCTURES IN LOW-CARBON STEEL
INAGAKI, H
[J]. TETSU TO HAGANE-JOURNAL OF THE IRON AND STEEL INSTITUTE OF JAPAN, 1992, 78 (11): : 1635 - 1643
[4] Digital identification scheme for steel microstructures in low-carbon steel
Terasaki, Hidenori
Miyahara, Yu
Hayashi, Kotaro
Moriguchi, Koji
Morito, Shigekazu
[J]. MATERIALS CHARACTERIZATION, 2017, 129 : 305 - 312
[5] SULFUR IN LOW-CARBON STEEL FOR DEEP DRAWING
GRIGORKIN, VI
GRIGORKIN, OV
ZEMSKII, SV
[J]. STEEL IN THE USSR, 1983, 13 (04): : 153 - 156
[6] Cyclic Yield Characterization for Low-Carbon Steel with HAZ Microstructures
Nishikawa, Hide-aki
Furuya, Yoshiyuki
[J]. MATERIALS TRANSACTIONS, 2019, 60 (02) : 207 - 212
[7] FATIGUE CRACK INITIATION IN QUENCHED LOW-CARBON STEEL MICROSTRUCTURES
SOLBERG, JK
[J]. MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 1988, 101 : 39 - 46
[8] Sulfur in Low-Carbon Steel for Deep Drawing.
Grigorkin, V.I.
Grigorkin, O.V.
Zemskii, S.V.
[J]. Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya, 1983, (04): : 59 - 64
[9] Orientation in low-carbon deep-drawing steel
Stanley, JK
[J]. TRANSACTIONS OF THE AMERICAN INSTITUTE OF MINING AND METALLURGICAL ENGINEERS, 1944, 158 : 354 - 363
[10] Effect of Starting Microstructures on the Reverse Transformation Kinetics in Low-Carbon Steel
Hou, Junhua
He, Binbin
[J]. METALS, 2020, 10 (12) : 1 - 12

← 1 2 3 4 5 →