Minerals boundary detection in petrographic thin sections image using ArcGIS software

Abstract

In this paper, a new method for mineral boundary detection is proposed using a model prepared in ArcGIS ModelBuilder tool. Required data for this method are gray scale images taken from petrographic thin sections. The images are captured in 19 numbers through 90° polarizers and lambda plate rotation with 5° intervals while the microscope table is fixed. Mineral boundaries are detected using the ArcGIS software by comparison of colour intensity amongst the adjacent minerals in sequential images. The presented method is fast and accurate to detect favorite grain boundaries from thin sections, and is able to create a powerful database containing grain shape characteristics. Petrographic study on four rock samples demonstrates that the results of grain boundary detection by the model without operator intervention, are more than 80 percent correlated with manual boundary detection method.

Keywords

References

[1] Heilbronner R.P., Pauli C., “Integrated spatial and orientation analysis of quartz c-axes by computer aided microscopy”, Journal of Structural Geology 15 (1993) 369-382.

[2] Barraud J., “The use of watershed segmentation and GIS software for textural analysis of thin sections”, Journal of Volcanology and Geothermal Research 154 (2006) 17-33.

[3] Starkey J., Samantaray A.K., “Edge detection in petrographic images”, Journal of Microscopy 172(3) (1993) 263-266.

[4] Canny J., “A computational approach to edge detection”, IEEE Transactions on Pattern Analysis and Machine Intelligence 8(6) (1986) 679-698.

[5] Goodchild J.S., Fueten F., “Edge detection in petrographic images using the rotating polarizer stage”, Computers & Geosciences 24 (1998) 745-751.

[6] Fueten F., Mason J., “An artificial neural net assisted approach to editing edges in petrographic images collected with the rotating polarizer stage”, Computers & Geosciences 33 (2007) 1176-1188.

[7] Li Y., Onasch C.M., Guo Y., “GIS-based detection of grain boundaries”, Journal of Structural Geology 30 (2008) 431-443.

[8] Heilbronner R., “Automatic grain boundary detection and grain size analysis using polarization micrographs or orientation images”, Journal of Structural Geology 22 (2000) 969-981.

[9] Bartozzi M., Boyle A.P., Prior D.J., “Automated grain boundary detection and classification in orientation contrast images”, Journal of Structural Geology 22 (2000) 1569-1579.

[10] Choudhury K.R., Meere P.A., Mulchrone K.F., “Automated grain boundary detection by CASRG”, Journal of Structural Geology 28 (2006) 363-375.

[15] Obara B., “An image processing algorithm for the reversed transformation of rotated microscope images”, Computers & Geosciences 33 (2007) 853-859.

[11] Zhou Y., Starkey J., Mansinha L., “Segmentation of petrographic images by integrating edge detection and region growing”, Computers & Geosciences 30 (2004) 817-831.

[12] Obara B., “A new algorithm using image colour system transformation for rock grain segmentation”, Mineralogy and Petrology 91 (2007) 271-285.

[13] Fueten F., Goodchild J.S., “Quartz c-axis orientation determination using the rotating polarizer microscope”, Journal of Structural Geology 23 (2001) 895-902.

[14] Stockhert B., Duyster J., “Discontinuous grain growth in recrystallised vein quartz-implications for grain boundary structure, grain boundary mobility, crystallographic preferred orientation, and stress history”, Journal of Structural Geology 21 (1999) 1477-1490.

[16] Ozanian T.R., Phillips R., “Enhancement of fluoroscopic images with varying contrast”, Computer Methods and Programs in Biomedicine 65 (2001) 1-16.

[17] Salem N.M., Nandi A.K., “Novel and adaptive contribution of the red channel in preprocessing of colour fundus images”, Journal of the Franklin Institute 344(3-4) (2007) 243-256.

[18] Chen T.J., Chuang K.S., Chen S., Lu J.C., Shiao Y.H., “A Novel Image Smoothing Filter Using Membership Function”, Journal of Digital Imaging 20(4) (2007) 381-392.

[19] Wang S.R., Sun Y.N., Chang F.M., “Artifact removal and texture-based rendering for visualization of 3D fetal ultrasound images”, Medical And Biological Engineering Computing, Online published, Springer, DOI 10.1007/s11517-007-0286-7 (2007).

[20] Obara B., “Identification of transcrystalline microcracks observed in microscope images of a dolomite structure using image analysis methods based on linear structuring element processing”, Computers & Geosciences 33 (2007) 151-158.

[21] Fry N., “Random point distributions and strain measurement in rocks”, Tectonophysics 60 (1979) 806-807.

































































[22] Ramsay J.G., “Folding and Fracturing of Rocks”, McGraw-Hill, New York (1967).

[23] Lisle R.J., “Geological Strain Analysis. A Manual for the Rf/Φ Technique”, Pergamon Press (1985).

[24] Fernandez F.J., Menendez-Duarte R., Aller J., Bastida F., “Application of geographical information systems to shape fabric analysis. In: Bruhn, D., Burlini, L. (Eds.), High-Strain Zones: Structure and Physical Properties”, Geological Society of London Special Publication 245 (2005) 409-420.

[25] Guo Y., Onasch C.M., “Analysis of grain-scale deformation using a thin section GIS”, Geological Society of America Abstracts with Programs 33 (2001) 324.

Files

History

  • Receive Date: 02 July 2025
  • Revise Date: 04 February 2026
  • Accept Date: 02 July 2025

Share

How to cite

Statistics