Histograms of oriented gradients for automatic detection of defective regions in thermograms

Jorge Erazo-Aux; H. Loaiza-Correa; A. D. Restrepo-Giron

doi:10.1364/AO.58.003620

Applied Optics
Vol. 58,
Issue 13,
pp. 3620-3629
(2019)
•https://doi.org/10.1364/AO.58.003620

Histograms of oriented gradients for automatic detection of defective regions in thermograms

Jorge Erazo-Aux, H. Loaiza-Correa, and A. D. Restrepo-Giron

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Jorge Erazo-Aux, H. Loaiza-Correa, and A. D. Restrepo-Giron, "Histograms of oriented gradients for automatic detection of defective regions in thermograms," Appl. Opt. 58, 3620-3629 (2019)

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- Imaging Systems, Image Processing, and Displays
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About this Article
History
- Original Manuscript: January 15, 2019
- Revised Manuscript: April 5, 2019
- Manuscript Accepted: April 7, 2019
- Published: May 1, 2019

Abstract

This paper presents a new methodology for the automatic detection of defective regions of interest (d-ROI) in thermal images of composite materials. The images are acquired with pulsed thermography, and local histograms of oriented gradients are obtained by thermogram processing. This information is analyzed using a simple strategy to differentiate the material background from the defective areas. The procedure is independent of image contrast or enhancement; it does not require analysis of a complete sequence of images, nor does it involve heat transfer models or the extraction of nonuniform heating information. The methodology is tested with synthetic images of a carbon fiber-reinforced plastic sample, containing diameter/depth ratio defects with different values (between 150 and 0.56). The performance of the d-ROI detection method is validated using the area under the ROC curve (AUC) measure, generally obtaining a maximum average value of 0.949 with variations between 0.891 and 0.993 for all the defective depth and size conditions studied. In addition, this method is highly robust when detecting defects in 48.84% of the total number of images, as determined by the sequences analyzed with AUC values higher than 0.95. Outside the high detectability index range, the AUC performance increases abruptly and decays gradually. Recent literature proposes automatic detection of defects in thermograms yielding similar performances to those obtained with the proposed method; however, they require preprocessing of all the thermograms to improve image contrast and visibility and to attenuate the adverse effect of nonuniform heating, which affects the implementation complexity and the computational cost.

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Material	Conductivity [W/m·K]	Heat Capacity [W·s/Kg·K]	Density $ρ$ $[Kg / m^{3}]$
CFRP	0.7	1200	1600
Plexiglass	0.19	1470	1190
Air	0.07	928	1.3

Number of Defects	Lateral Dimension (D) [mm]	Thickness (G) [mm]	Depth (P) [mm]	Spatial Coordinates ^a [pixel]
8	[1; 2; 3; 6; 9; 12; 15]	0.1	[0.1; 0.4; 0.7; 1.0; 1.3; 1.6; 1.8]	Def.1: (40,40), def.2: (150,30).
				Def.3: (90,90), def.4: (60,110).
				Def. 5: (120,120), def. 6: (40,140).
				Def. 7: (150,150), def. 8: (10,170).

Pulse Width	Energy Density	Acquisition Frequency (Hz)	Time Frame (s)
$1260 \times 10^{- 5} s$	$1 \times 10^{5} W / m^{2}$	157	9

Depth $P$ (mm)	${AUC}_{\max^{˜}}$	Images with AUC $> 0.95$	(%) Images with AUC $> 0.95$
0.1	0.991	3518	35.17
0.4	0.993	6550	65.48
0.7	0.993	7213	72.11
1.0	0.984	6590	65.88
1.3	0.949	5616	56.14
1.6	0.845	3636	36.35
1.8	0.891	1076	10.76
Overall Result	0.949	34,199	48.84

Material	Conductivity [W/m·K]	Heat Capacity [W·s/Kg·K]	Density $ρ$ $[Kg / m^{3}]$
CFRP	0.7	1200	1600
Plexiglass	0.19	1470	1190
Air	0.07	928	1.3

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Applied Optics