Predicting the strength of European beech (Fagus sylvatica L.) boards using image-based local fibre direction data

Ehrhart, Thomas; Palma, Pedro; Schubert, Mark; Steiger, René; Frangi, Andréa

doi:10.1007/s00226-021-01347-w

Cited by 14 publications

(15 citation statements)

References 47 publications

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“…The high accuracy of our models suggests that a recording and subsequent processing of data of surface patterns of the wood surface can sufficiently display the relationship between hierarchical wood structure and selective mechanical properties. This is in line with the emergence property of fibre-based composites discussed by Jeronimidis & Vincent [18] and the results obtained by Ehrhart et al in a similar study [16]. They used image analysis with predefined indicators of wood fibre directions to infer the strength of beech lamellae.…”

Section: Discussionsupporting

confidence: 84%

“…Therefore, probing the complexity of wood is indispensable for understanding better the relationship between structure and properties. Indeed, a recent study showed that local fibre direction data, generated based on the analysis of the spindle pattern of bigger rays on tangential surfaces, could improve the prediction of the tensile strength parallel to the grain of European beech (Fagus sylvatica) lamellae [16]. In addition, Olsson et al developed a novel strength grading method, approved for the European market, based on fibre orientation and dynamic excitation of Norway spruce lamellae [12,20].…”

Section: Fibres As Building Blocksmentioning

confidence: 99%

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Probing the complexity of wood with computer vision: from pixels to properties

Lukovic,

Ciernik,

Müller

et al. 2024

J. R. Soc. Interface.

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We use data produced by industrial wood grading machines to train a machine learning model for predicting strength-related properties of wood lamellae from colour images of their surfaces. The focus was on samples of Norway spruce ( Picea abies ) wood, which display visible fibre pattern formations on their surfaces. We used a pre-trained machine learning model based on the residual network ResNet50 that we trained with over 15 000 high-definition images labelled with the indicating properties measured by the grading machine. With the help of augmentation techniques, we were able to achieve a coefficient of determination ( R 2 ) value of just over 0.9. Considering the ever-increasing demand for construction-grade wood, we argue that computer vision should be considered a viable option for the automatic sorting and grading of wood lamellae in the future.

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Section: Discussionsupporting

confidence: 84%

Section: Fibres As Building Blocksmentioning

confidence: 99%

Probing the complexity of wood with computer vision: from pixels to properties

Lukovic,

Ciernik,

Müller

et al. 2024

J. R. Soc. Interface.

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“…It is of no surprise that such linear models perform poorly, placing the coefficient of determination somewhere between 0.45 and 0.7 . From a scientific perspective, so far there have been very few attempts to use ML to improve the machine grading of wood. − The major part of research in the field of machine grading is dedicated to finding new measurement techniques and better indicating properties in order to improve the accuracy of the prediction …”

Section: Managing Wood Complexity With Machine Learningmentioning

confidence: 99%

“…The introduction of ML into the manufacturing process of engineered wood products would provide the opportunity to predict in real time the performance characteristics of the final product, to carry out production according to certain specifications, and to reduce part of the raw material consumption and/or increase the overall throughput. ,, While traditional ML methods based on supervised learning (labeled data) have been used with some success to predict the quality of wood products, ,,− the limited availability of labeled data is the major hurdle for further improving ML model performance.…”

Section: Managing Wood Complexity With Machine Learningmentioning

confidence: 99%

Sustainability in Wood Products: A New Perspective for Handling Natural Diversity

2022

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Wood is a renewable resource with excellent qualities and the potential to become a key element of a future bioeconomy. The increasing environmental awareness and drive to achieve sustainability is leading to a resurgence of research on wood materials. Nevertheless, the global climate changes and associated consequences will soon challenge the wood-value chains in several regions (e.g., central Europe). To cope with these challenges, it is necessary to rethink the current practice of wood sourcing and transformation. The goal of this review is to address the intrinsic natural diversity of wood, from its origin to its technological consequences for the present and future manufacturing of wood products. So far, industrial processes have been optimized to repress the variability of wood properties, enabling more efficient processing and production of reliable products. However, the need to preserve biodiversity and the impact of climate change on forests call for new wood processing techniques and green chemistry protocols for wood modification as enabling factors necessary for managing a more diverse wood provision in the future. This article discusses the past developments that have resulted in the current wood value chains and provides a perspective about how natural variability could be turned into an asset for making truly sustainable wood products. After briefly introducing the chemical and structural complexity of wood, the methods conventionally adopted for industrial homogenization and modification of wood are discussed in relation to their evolution toward increased sustainability. Finally, a perspective is given on technological potentials of machine learning techniques and of novel functional wood materials. Here the main message is that through a combination of sustainable forestry, adherence to green chemistry principles and adapted processes based on machine learning, the wood industry could not only overcome current challenges but also thrive in the near future despite the awaiting challenges.

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“…Traditional ML methods based on supervised learning have been used with some success to predict the quality of wood products (Barnes 2001;Gupta et al 2007;André et al 2008;Esteban et al 2011;Bardak et al 2016a, b;Schubert and Kläusler 2020;van Blokland et al 2021;Ehrhart et al 2022;Rahimi and Avramidis 2022). For example, artificial neural networks (ANN), support vector machines (SVM), and Naive Bayes (NB) models were used to classify the quality of thermally modified wood (Nasir et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Semi-supervised learning for quality control of high-value wood products

Schubert

Sonderegger²,

Luković

et al. 2022

Wood Sci Technol

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The quality control of wood products is often only checked at the end of the production process so that countermeasures can only be taken with a time delay in the event of fluctuations in product quality. This often leads to unnecessary and cost-intensive rejects. Furthermore, since quality control often requires additional procedural steps to be performed by a skilled worker, testing is time-consuming and costly. While traditional machine learning (ML) methods based on supervised learning have been used in the field with some success, the limited availability of labeled data is the major hurdle for further improving model performance. In the present study, the potential of enhancing the performance of the ML methods random forest (RF) and support vector machines (SVM) for quality classification by using semi-supervised learning (SSL) was investigated. Labeled and unlabeled data were provided by Swiss Wood Solutions AG, which produces densified wood for high-value wood products such as musical instruments. The developed approach includes labeling of the unlabeled data using SSL, training and 10k cross-validation of the ML algorithms RF and SVM, and determining the generalization ability using the hold-out test set. Based on the evaluation indices such as accuracy, F1-score, recall, false-positive-rate and confusion matrices, it was shown that SSL could enhance the prediction performance of the quality classification of ML models compared to the conventional supervised learning method. Despite having a small dataset, the work paves the way for future applications of SSL for wood quality assessment.

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Predicting the strength of European beech (Fagus sylvatica L.) boards using image-based local fibre direction data

Cited by 14 publications

References 47 publications

Probing the complexity of wood with computer vision: from pixels to properties

Probing the complexity of wood with computer vision: from pixels to properties

Sustainability in Wood Products: A New Perspective for Handling Natural Diversity

Semi-supervised learning for quality control of high-value wood products

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