AUTOMATIC MICROSTRUCTURE GRAIN COUNT USING SUPPORT VECTOR REGRESSION

Authors

  • Gajalakshmi K Department of Computer Science and Engineering, Annamalai University, Tamilnadu, India
  • Palanivel S Department of Computer Science and Engineering, Annamalai University, Tamilnadu, India
  • Nalini N J Department of Computer Science and Engineering, Annamalai University, Tamilnadu, India
  • Saravanan S Department of Mechanical Engineering, Annamalai University, Tamilnadu, India

Keywords:

Support Vector Regression, Microstructure, Grain count, Automatic thresholding

Abstract

Grain count determination is an important task in microstructural analysis, requires long time while performing manually. Nowadays, automatic techniques for the grain size determination are implemented. Although the automatic techniques are documented on the ASTM standards, the major drawback is the non availability of quality digital microstructural images. The quality of microstructure depends on various factors viz., illumination, noise, low contrast, poor boundary definition etc. The present work is focused on a novel methodology that enables a clear definition of the grain and its boundary for an accurate automatic grain count and size through pattern classification technique, employing support vector regression (SVR) method.

Downloads

Download data is not yet available.

References

Dutta S Das A Barat K Roy H (2012), “Automatic characterization of fracture surfaces of AISI 304LN stainless steel using image texture analysis”, Measurement, Vol.45 (5), 1140–1150.

Coster M Arnould A Chermant J L Chermant L and Chartier T (2004), “The use of image analysis for sintering investigations the example of CeO2 doped with TiO2”, J. Eur. Ceram. Soc., Vol.25 (15), 3427–3435.

Dengiz O Smith A E and Nettleship I (2005), “Grain boundary detection in microstructure images using computational intelligence”, Computers in Industry, Vol.56 (8-9), 854-866.

Colás R (2001), “On the variation of grain size and fractal dimension in an austenitic stainless steel”, Mater. Charact, Vol. 46 (5), 353-358.

Maropoulos S Karagiannis S and Ridley N (2006), “Factors affecting prior austenite grain size in low alloy steel”, J. Mater Sci., Vol. 42, 1309-1320.

Tarpani J R and Spinelli D (2003), “Grain size effects in the charpy impact energy of a thermally embrittled RPV steel”, J. Mater Sci., Vol. 38 (7), 1493-1498.

Heilbronner R (2000), “Automatic grain boundary detection and grain size analysis using polarization micrographs or orientation images”, J. Struct., Geol., Vol.22 (7), 969–981.

Lu B Lin Z and Wang H (2011), “Grain identification of polarizing images with level set method, IEEE 3rd International Conference on Comma Software and Net”, 192–195.

Peregrina-Barreto H Terol-Villalobos I R Rangel-Magdaleno J J Herrera Navarro A M Morales-Hernández L A and Manríquez-Guerrero F (2013), “Automatic grain size determination in microstructures using image processing”, Measurement, Vol.46, 249–258.

ASTM Standard E112-12 (2012), “Standard test methods for determining average grain size”, ASTM International.

Wu C H Ho J M and Lee D T (2004), “Travel-Time Prediction with Support Vector Regression”, IEEE transactions on intelligent transportation systems, Vol. 5(4), 276-281.

Zhang L Xu Z Wei S Ren X Wang M (2016), “Grain Size Automatic Determination for 7050 Al Alloy based on a Fuzzy Logic Method”, Rare Metal Materials and Engineering, Vol. 45(3), 548-554.

Downloads

Published

2017-03-01

Issue

Section

Articles

How to Cite

[1]
“AUTOMATIC MICROSTRUCTURE GRAIN COUNT USING SUPPORT VECTOR REGRESSION”, JME, vol. 12, no. 1, pp. 029–032, Mar. 2017, Accessed: Nov. 22, 2024. [Online]. Available: https://smenec.org/index.php/1/article/view/176

Similar Articles

21-30 of 128

You may also start an advanced similarity search for this article.

Most read articles by the same author(s)

1 2 > >>