3D morphology of internal defects in wooden products based on computed tomography

Zhao, G., Liu, C., Qiu, Z., Deng, Z., and Gong, J. (2021). "3D morphology of internal defects in wooden products based on computed tomography," BioResources 16(3), 6267-6280.

Abstract

A visualization method was used in this work for the 3D morphology of internal defects in wooden products using a Philips Brilliance 16 computed tomography (CT). To obtain a high-quality 3D digital model, the original images from the CT scan were segmented to manually color the cross- and vertical sections of the wooden specimen. Through coloring, the reconstructed model showed the accurate 3D morphology of internal defects, such as cracks, wormholes, and decay parts, as well as clear shapes of borer excrement, nails, bark, and wood parts of the specimen. The results suggest that this method provides precise 3D models of different types of defects in the wooden specimen. It can also accurately measure the size and angle of the defects at any position for further observation. This method can be effectively used for non-destructive testing of wooden products and wooden cultural relics and can provide accurate scales of defects and intuitive 3D models for wooden products and wooden cultural relics restoration.

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3D Morphology of Internal Defects in Wooden Products Based on Computed Tomography

Guiling Zhao,^aChang Liu,^a,* Zhaowen Qiu,^b,c, Zongji Deng,^band Jinhua Gong ^d

Keywords: Three-dimensional cultural wooden relics segmentation; Computed tomography; Total variation; 3D reconstruction

Contact information: a: Northeast Agricultural University, Harbin, P.R. China, 150040; b: Northeast Forestry University Harbin, China, 150040; c: HeiLongjiang Tuomeng Technology Co., Ltd.; d: Department of Biomedical Sciences, City University of Hong Kong; *Corresponding author: 1368817540@qq.com

GRAPHICAL ABSTRACT

INTRODUCTION

There are a large number of wooden cultural relics in the world, mainly including wooden buildings and furniture. These wooden cultural relics may be discolored, cracked, decayed by natural damage, such as wind, sun, rain, insects, etc., plus incur man-made damage, and their quantity decreases daily. Wooden cultural relics, such as ancient buildings and furniture, are often in good appearance, but the interior may have been damaged. Accurately judging the location, 3D shape, and precise scale of internal damage in wooden cultural relics is helpful for interventional protection. Therefore, the study of the 3D morphology of internal defects in wooden products is important.

At present, the method of research on internal defects of wood and wooden products mainly focuses on non-destructive testing using stress wave technology, and such methods are affected by wood temperature, moisture content, and compressive strength, and the accuracy is not high enough (Li 2016; Gao et al. 2018). In 2010, Marino et al. used acoustic tomography to detect the pith location of chestnut. They analyzed the velocity gradient by correlating the longitudinal stress wave velocity value with the distance from the velocity measurement point to the pulp. It was demonstrated that the longitudinal velocity had a statistically significant relationship with the distance from the center of a log. In 2010, Hasegawa et al. (2010) applied the acoustoelastic technique to the nondestructive stress analysis of wood structures and carried out an experimental study on the acoustoelastic effect of Japanese fast-growing trees. Silva et al. (2014) used a nondestructive technique, with application of stress waves, for the evaluation of hardness of timber species in the Central Amazon. Liu et al. (2015) proposed a mathematical model of stress wave propagation on the cross-section of healthy trees and in 2017, Zhang et al. established a model of the propagation velocity of stress waves on the longitudinal section of wood, which has a certain contribution for the development of wood internal imaging technology. Li et al. (2016) stated that the stress wave velocity patterns can be used to diagnosis internal defects in urban trees and improve the accuracy of 3D tomographic images in tree inspection applications. Chen et al. (2016) evaluated the mechanical properties of wood by nondestructive testing. Non-destructive and static mechanical tests of Cunninghamia lanceolata and Ulmus rubra were carried out. With the development of computer technology in recent years, researchers have tried to use algorithms to obtain internal images of wooden specimen via stress wave detection (Du 2015; Wei et al. 2019). In 2015, Chen et al. proposed a 3D stress wave imaging method for wood internal defects based on the Top-k Inverse Distance Weighted (TIDW) algorithm, and initially obtained the 3D images of the defects. Du et al. (2019) established a 3D stress wave imaging method based on the Kriging algorithm. The average accuracy reached 89.1%, which can roughly reflect the location of internal defects and the degree of damage in wood. Referred to the building formula, Chang et al. (2021) made 131 small specimens and 10 scaled timber column specimens to study the prediction of compressive bearing capacity of internal defects in ancient wooden buildings. There have been some studies on the relationship between the small specimens’ wave resistance modulus and mechanics, non-destructive testing, and internal defects wood column compressive bearing capacity prediction, as well as a dangerous section judgment, and so on.

Computer tomography (CT) technology is mainly used in the medical field, and few studies have reported its application in wood and wooden cultural relic internal defects detection. For example, Ekevad (2004) used a series of pixel information of 2D CT images to calculate and analyze the internal fiber condition of the wood. Tsarouchas and Markaki (2011) proposes a method for extracting reliable architectural characteristics from complex porous structures using micro-computed tomography (μCT) images. Brodersen (2013) reviewed the traditional methods to reconstruct the origin of xylem, the application status of micro-computed tomography (mu-CT) in plant biology, and its technical issues. The mu-CT imaging method provides a new perspective for wood anatomy and emphasizes the importance of the relationship between wood structure and function. The authors’ previous study (Zhao et al. 2015) performed a 3D reconstruction of Guqin cavity and converted 2D CT images into 3D models (The instrument used in the test is General Electric (GE) Brightspeedexcel4 spiral CT). This method can display the complete internal structure of the Guqin and obtain the size information of the Guqin cavity, which can provide technical support for the production process and quality inspection, but its internal visualization direction is limited. A later study (Zhao et al. 2018) used CT technology (Philips 16 slice spiral CT produced in Holland was used in the experiment) to obtain a high-precision 3D model of wooden cultural relics. This method can perform virtual segmentation at any position and any angle inside the wooden cultural relics. After segmentation, the internal wood structure can be clearly visualized, and the parameter value can be adjusted to distinguish the material density, but the 3D defect morphology inside the wood specimen was not studied. The purpose of this study is to investigate the 3D morphology of internal defects in wooden products using CT technology.

Experimental Preparation

Wooden specimens were tested using a Philips Brilliance 16 CT (model A; Amsterdam, Netherlands). The parameters of the CT are listed in Table 1. The CT images of the defective parts were segregated by Matlab (MathWorks, v.2016, Natick, MA, USA). In the diagnostic image processing software, the cross-section images were generated by analyzing the vertical section images. Each CT image contains the corresponding sample coordinate information. After importing the DICOM3.0 format of CT image into the diagnostic image processing software, the coronal and sagittal images can be obtained. It can be understood as a book, in which each page is a data set. One can imagine the pages of the book compiled together. As in the case of the book, information can be located either front to back or relative to the sides. The artificial colouring process was completed by use of software from Heilongjiang Tuomeng Technology Co., Ltd., Harbin, China. All types of detects of the specimens were visualized using the 3D visual film reading terminal (Heilongjiang Tuomeng Technology Co., Ltd., Harbin, China).

Table 1. Philips Brilliance 16 CT (model A) Main Parameters

Four steps were prepared for the experiment. The first step was to obtain CT scanning images using the settings in Table 1. The CT scan test was completed in the CT scan room of the tertiary hospital (Harbin, China) with the same environmental conditions of a patient CT scan test. The second step used Matlab (MathWorks, v.2016, Natick, MA, USA) for image segmentation experiments in a Windows 7 operating system (Microsoft Corp., Redmond, WA, USA) to verify the effectiveness of this method. In the third step, the candidate cross- and vertical sections of CT images were manually colored in the self-developed software (Diagnostic image processing software, Heilongjiang Tuomeng Technology Co., Ltd., Harbin, China) for further 3D defect morphology analysis. The fourth step was to complete the 3D reconstruction of the defect morphology in the specimen from multiple perspectives by adjusting settings, such as transparency and display status, in the patented software independently developed by Tuomeng Technology (3D visual film reading terminal, Heilongjiang Tuomeng Technology Co., Ltd., Harbin, China).

Materials

Two wooden specimens were tested in this study, and the basic information is shown in Table 2. Sample 1 was obtained from unused materials from the Wood Science Laboratory of Northeast Forestry University (Harbin, China). Sample 2 was purchased from Hongcun tourist souvenir store of Yi County (Huangshan City, Anhui Province, China).

Table 2. Basic Information of Specimens

3D Visualization

The defects in the specimen have similar CT image grayscales, and some of them connect to each other, which raises the difficulty to distinguish them. It is reported that TVL1 algorithm has good edge protection and multi-scale decomposition property that can solve the grayscale and connection problem; thus it was used to conduct the 3D visualization experiment. In order to have higher accuracy, the TVL1 was improved to a 3D-TVL1 version based on the edge-weighted total variation model,

as proposed by Brodersen (2013) et al. The 3D-TVL1 algorithm inherits the property of TVL1 algorithm and has fast calculation speed and high locating accuracy. It is widely used in the field of medical image segmentation, and it is also suitable for wooden product CT image segmentation (Zhao et al. 2017). With the introduction of the discrete method and fast primal-dual projection, the 3D-TVL1 segmentation model can provide an ideal CT image segmentation effect.

There are mainly three steps to complete the 3D visualization process. Firstly, the 3D-TVL1 is used to segment the CT images of a wooden specimen. Then, the defect parts of the candidate CT images are labelled after the segmentation process. In this step, the decay xylem, wormholes, and cracks are considered as the internal morphology objectives and the bark, borer excrement, and iron nails are considered as the component morphology objectives. Finally, the labeled images are used to conduct 3D reconstruction. This process is summarized in the flow chart in Fig. 1.

Fig. 1. 3D Visualization Flow Chart

Experimental Analysis

To verify the validation of the 3D visualization method of the wooden specimen, it was analyzed by MATALAB on Windows 7 for image segmentation. The N1 specimen was scanned vertically using the Philips Brilliance 16 CT (Model A), the layer thickness was set as 0.8 mm, and 700 vertical-section CT images in Dicom format were obtained.

Section CT image segmentation and generation

The vertical section CT images of the specimen were segmented using 3DL1. The 128^th, 148^th, and 168^th vertical section CT images (Fig. 2) from the 700 images were selected for the segmentation to remove the non-specimen background, the resulting images are shown in Fig. 3.

Fig. 2. Original CT images of wood specimens (vertical section); A: 128^th cross-section; B: 148^th cross-section; C: 168^th cross-section

Fig. 3. Partial CT images after 3DL1 segmentation (vertical section); A: 128^th cross-section; B: 148^th cross-section; C: 168^th cross-section

The cross-section CT images of the specimen were generated from the vertical section images using the diagnostic image processing software. The Dicom format CT images were input into the software and 511 cross-section CT images were obtained. The 225th, 245th, and 265th cross-sections are shown in Fig. 4.

Fig. 4. Using diagnostic image processing software, cross-sectional CT images of specimens were generated from vertical section images; A: 225th cross-section; B: 245th cross-section; C: 265th cross-section

Coloring

In order to obtain a 3D digital model of the defects in the specimen, the vertical and cross-section images were manually colored. The purpose of coloring process was to distinguish defects, such as wormholes and cracks, from the specimen original component. The defect boundary was manually identified according to the section CT image Dicom data, and then the defect area was colored. With different pixel information after coloring, defects and original components can be recognized during the 3D reconstruction process.

Cracks, wormholes, and nail holes are all hollow defects in the specimen and present similar grayscale threshold in the Dicom data; hence the same coloring method is applied on these defects. Random examples of colored wormholes in vertical and cross- sections are shown in Figs. 5 and 6, respectively.

Fig. 5. Wormhole coloring of CT images (vertical-section); A: 88^th cross-section; B: 108^th cross-section; C: 128^th cross-section

Fig. 6. Wormhole coloring of CT images (cross-section); A: 205th cross-section; B: 225th cross-section; C: 245th cross-section

The staining of wormholes and cracks in wood was more objective because the boundary between the cavity and the surrounding wood was clear. However, the hand coloring of rotten wood has certain subjectivity. Because the decay part of wood is processed by observing the color change of the image, the darker the color, the more serious the decay. But the boundary between the rotten part and the surrounding wood is not clear. As shown in Figs. 7 and 8, the decay from the center to the periphery is a gradual process from heavy to light. Therefore, the color will be subject to the subjective influence of the experimenter. At present, there is no standard to judge the degree of decay.

Fig. 7. Colored decayed parts of the wooden specimen (vertical section); A: 188th cross-section; B: 208th cross-section; C: 228th cross-section

Fig. 8. Colored decayed parts of the wooden specimen (cross-section)

To color the borer excrement, the air in the hollow part of the wormhole needs to be colored, and then it is possible to subtract the borer excrement according to the Boolean operation to obtain a 3D model of the borer excrement.

Fig. 9. 3D morphology of defects in wooden specimen

Fig. 10. 3D morphology of large cracks, small cracks, and nail holes in the wooden specimen

3D reconstruction

The 3D reconstruction is completed via the self-developed software to perform 3D modeling of the colored CT images. The transparency of the wooden part can be set to a lower value to facilitate the observation of the 3D models of each type of defects. As shown in Fig. 9, if the transparency was 35, the 3D morphology of defects, such as large cracks, small cracks, nail holes, wormholes, and borer excrement can be seen clearly.

RESULTS AND DISCUSSION

In order to further visually and clearly observe the 3D morphology of defects in specimen, each type of defect/original component can be displayed individually by hiding other parts in the self-developed software. For example, the 3D morphology of cracks and nail holes is shown in Fig. 10 when the bark, wormholes, and borer excrement are hidden. Another function of this 3D model is to display all defects in one image for labelling and size measurement (Figs. 11 and 12). However, most of the defects in wood are irregular, so it is impossible to calculate the defect volume with the traditional physical formula. Therefore, how to calculate the volume of the irregular defects through the pixel value is the focus of the next stage research.

With the same CT scanning equipment used in sample 1, the same scanning parameters were set to scan sample 2. 275 CT images were obtained. Using the acquired CT image, the 3D shape of the crack in sample 2 was obtained by 3D reconstruction of the crack in sample 1. The 3D shape of the crack is shown in Fig. 12.

Fig. 11. 3D morphology and size information of each defect in the wooden specimen

Fig. 12. 3D model of specimen N2 and multi-angle 3D diagram of crack part

The current coloring process requires the participation of professional personnel, and the CT machine has a large size and weight, which limits the application conditions of this method. Furthermore, the CT equipment used in this study is for medical tests, such that the capacity of the scanning chamber restricts the size of specimens to be tested. All these factors impede the application of this method.

CONCLUSIONS

The authors’ method can visualize the complex morphology of defects inside wooden products and can accurately measure their size information at any position and any angle. Through accurate 3D morphology analysis of the location, shape, and size of defects, an intuitive, precise, customized, and scientific restoration protocol of wooden products and cultural relics could be provided.

The authors’ method can generate accurate 3D morphology information of defects in wooden products, while the volume of each defect cannot be calculated yet due to the irregular shape and size of each defect. This method is limited to the size of the specimen, and the next step is to focus on the image acquisition method of the related specimen of mobile CT.

ACKNOWLEDGMENTS

This work was supported by “Heilongjiang philosophy and Social Science Foundation” (2020.9-2021.12) (grant number 20YSB056, China).

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Article submitted: February 26, 2021; Peer review completed: June 26, 2021; Revised version received and accepted: July 9, 2021; Published: July 27, 2021.

DOI: 10.15376/biores.16.3.6267-6280