nach oben

Progress in Additive Manufacturing

Erschienen in:

18.12.2022 | Full Research Article

Investigation of long short-term memory networks for real-time process monitoring in fused deposition modeling

verfasst von: Ahmed Shany Khusheef, Mohammad Shahbazi, Ramin Hashemi

Erschienen in: Progress in Additive Manufacturing | Ausgabe 5/2023

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

To improve additive manufacturing (AM), from being limited to creating prototypes to fabricating functional parts with low failure rates and high precision, several challenges have to be addressed. In-situ AM process monitoring plays a central role in the quality assurance of fabricated parts during the actual build job. This paper studies the feasibility of utilizing long short-term memory (LSTM) networks in the real-time monitoring of fused deposition modeling (FDM) processes for detecting pre-specified types of anomalies. Several hybrid LSTM models are developed and validated using the time-series sensor data collected during the operation of a Delta 3D printer. In particular, two distinct approaches are tailored to pre-process the sensor data before being fed into the LSTM classifiers: (i) a handcrafted feature extraction method that leverages statistical abstractions of the data; and (ii) an intelligent feature extraction method through the so-called anomaly images, adopted from the human activity recognition literature. The results show that all image-based LSTM models are more reliable and robust against noise than the models trained using handcrafted feature extraction. The highest mean accuracy of the LSTM models is 99.85%, and the required time for a prediction task is sub-millisecond, making the model feasible for real-time process monitoring and anomaly detection. It is also shown that the proposed system substantially outperforms the traditional machine learning alternatives.

Vorheriger Artikel Numerical and experimental investigation of the geometry dependent layer-wise evolution of temperature during laser powder bed fusion of Ti–6Al–4V

Nächster Artikel The influence of laser surface remelting on the in vitro cell viability of additively manufactured Ti–6Al–4V plates

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

B. Stucker, D. W. Rosen, and I. Gibson, Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing. 2013.

Liu C, Le Roux L, Ji Z, Kerfriden P, Lacan F, Bigot S (2020) Machine Learning-enabled feedback loops for metal powder bed fusion additive manufacturing. Procedia Comput Sci 176:2586–2595. https://doi.org/10.1016/j.procs.2020.09.314CrossRef

Gao W et al (2015) The status, challenges, and future of additive manufacturing in engineering. CAD Comput Aided Des 69:65–89. https://doi.org/10.1016/j.cad.2015.04.001CrossRef

M. Mani, B. Lane, A. Donmez, S. Feng, S. Moylan, and R. Fesperman, “Measurement Science Needs for Real-time Control of Additive Manufacturing Powder Bed Fusion Processes,” Natl. Inst. Stand. Technol., no. February, 2015.

Grasso M, Colosimo BM (2017) Process defects and in situ monitoring methods in metal powder bed fusion: A review”. Meas. Sci. Technol. 28:2017. https://doi.org/10.1088/1361-6501/aa5c4fCrossRef

Kim DB, Witherell P, Lipman R, Feng SC (2015) Streamlining the additive manufacturing digital spectrum: a systems approach. Addit Manuf 5:20–30. https://doi.org/10.1016/j.addma.2014.10.004CrossRef

M. Aminzadeh, “A Machine Vision System for In-Situ Quality Inspection in Metal Powder-Bed Additive Manufacturin,” no. December, p. 257, 2016, [Online]. https://smartech.gatech.edu/handle/1853/56291.

Montazeri M, Nassar AR, Stutzman CB, Rao P (2019) Heterogeneous sensor-based condition monitoring in directed energy deposition”. Addit. Manuf. 30:2019. https://doi.org/10.1016/j.addma.2019.100916CrossRef

Li Z, Zhang Z, Shi J, Wu D (2019) Prediction of surface roughness in extrusion-based additive manufacturing with machine learning. Robot Comput Integr Manuf 57:488–495. https://doi.org/10.1016/j.rcim.2019.01.004CrossRef

10.

Yang Z, Jin L, Yan Y, Mei Y (2018) Filament breakage monitoring in fused deposition modeling using acoustic emission technique. Sensors (Switzerland) 18(3):1–16. https://doi.org/10.3390/s18030749CrossRef

11.

Shevchik SA, Kenel C, Leinenbach C, Wasmer K (2018) Acoustic emission for in situ quality monitoring in additive manufacturing using spectral convolutional neural networks. Addit Manuf 21:598–604. https://doi.org/10.1016/j.addma.2017.11.012CrossRef

12.

Kou R, S. wei Lian, N. Xie, B. er Lu, and X. mei Liu, (2022) Image-based tool condition monitoring based on convolution neural network in turning process. Int. J. Adv. Manuf. Technol 119:3279–3291. https://doi.org/10.1007/s00170-021-08282-xCrossRef

13.

Ahmad Z, Khan N (2021) Inertial sensor data to image encoding for human action recognition. IEEE Sens J 21(9):10978–10988. https://doi.org/10.1109/JSEN.2021.3062261CrossRef

14.

Martínez-Arellano G, Terrazas G, Ratchev S (2019) Tool wear classification using time series imaging and deep learning. Int J Adv Manuf Technol 104(9–12):3647–3662. https://doi.org/10.1007/s00170-019-04090-6CrossRef

15.

P. K. Sharma, M. Dennison, and A. Raglin, “IoT solutions with multi-sensor fusion and signal-image encoding for secure data transfer and decision making,” arXiv Prepr. arXiv2106.01497, pp. 25–39, 2020.

16.

W. Jiang and Z. Yin (2015) Human activity recognition using wearable sensors by deep convolutional neural networks. pp. 1307–1310, 2015.

17.

Szydlo T, Sendorek J, Windak M, Brzoza-Woch R (2021) Dataset for anomalies detection in 3D printing. Int Conf Comput Sci 2021:647–653. https://doi.org/10.1007/978-3-030-77970-2_50CrossRef

18.

Lecun Y, Bengio Y, Hinton G (2015) Deep learning. Nature 521(7553):436–444. https://doi.org/10.1038/nature14539CrossRef

19.

Senin N, Leach R (2018) Information-rich surface metrology. Procedia CIRP 70:47–52. https://doi.org/10.1016/j.procir.2018.02.026CrossRef

20.

Fu Y, Downey A, Yuan L, Pratt A, Balogun Y (2020) In situ monitoring for fused filament fabrication process: a review. Addit. Manuf 38:2. https://doi.org/10.1016/j.addma.2020.101749CrossRef

21.

Wu D, Wei Y, Terpenny J (2019) Predictive modelling of surface roughness in fused deposition modelling using data fusion. Int J Prod Res 57(12):3992–4006. https://doi.org/10.1080/00207543.2018.1505058CrossRef

22.

Wu H, Yu Z, Wang Y (2016) Real-time FDM machine condition monitoring and diagnosis based on acoustic emission and hidden semi-Markov model. Int J Adv Manuf Technol. https://doi.org/10.1007/s00170-016-9548-6CrossRef

23.

Zhang Y, Hong GS, Ye D, Zhu K, Fuh JYH (2018) Extraction and evaluation of melt pool, plume and spatter information for powder-bed fusion AM process monitoring. Mater Des 156:458–469. https://doi.org/10.1016/j.matdes.2018.07.002CrossRef

24.

Narayanan BN, Beigh K, Loughnane G, Powar NU (2019) Support vector machine and convolutional neural network based approaches for defect detection in fused filament fabrication. Proc. SPIE 11139, Applications of Machine Learning, 1113913 (6 September 2019) 2019:36. https://doi.org/10.1117/12.2524915CrossRef

25.

Jin Z, Zhang Z, Gu GX (2020) Automated real-time detection and prediction of interlayer imperfections in additive manufacturing processes using artificial intelligence. Adv Intell Syst 2(1):1900130. https://doi.org/10.1002/aisy.201900130CrossRef

26.

Saluja A, Xie J, Fayazbakhsh K (2020) A closed-loop in-process warping detection system for fused filament fabrication using convolutional neural networks. J Manuf Process 58(2020):407–415. https://doi.org/10.1016/j.jmapro.2020.08.036CrossRef

27.

Jin Z, Zhang Z, Gu GX (2019) Autonomous in-situ correction of fused deposition modeling printers using computer vision and deep learning. Manuf Lett 22:11–15. https://doi.org/10.1016/j.mfglet.2019.09.005CrossRef

28.

Zhang J, Wang P, Gao RX (2019) Deep learning-based tensile strength prediction in fused deposition modeling. Comput Ind 107:11–21. https://doi.org/10.1016/j.compind.2019.01.011CrossRef

29.

Ren K, Chew Y, Zhang YF, Fuh JYH, Bi GJ (2020) Thermal field prediction for laser scanning paths in laser aided additive manufacturing by physics-based machine learning. Comput. Methods Appl. Mech. Eng 362:2020. https://doi.org/10.1016/j.cma.2019.112734CrossRef

30.

Tao W, Lai Z, Leu C, Yin Z (2018) Worker activity activity recognition recognition in in smart smart manufacturing manufacturing using using IMU and sEMG signals with convolution neural networks. Procedia Manuf 26:1159–1166. https://doi.org/10.1016/j.promfg.2018.07.152CrossRef

31.

Van Houdt G, Mosquera C, Nápoles G (2020) A review on the long short-term memory model. Artif Intell Rev 53(8):5929–5955. https://doi.org/10.1007/s10462-020-09838-1CrossRef

32.

J. Brownlee (2018) Deep Learning for Time Series Forecasting Predict the Future with MLPs , CNNs and LSTMs in Python. Machine Learning Mastery.

33.

Srivastava N, Hinton G, Krizhevsky A, Sutskever I, Salakhutdinov R (2014) Dropout: a simple way to prevent neural networks from overfitting. Phys Lett B 15(3–4):1929–1958. https://doi.org/10.1016/0370-2693(93)90272-JMathSciNetCrossRefMATH

34.

F. Chollet and & Others., “Keras.,” 2015. https://github.com/fchollet/keras.

35.

A. F. M. Agarap, “Deep Learning using Rectified Linear Units ( ReLU ),” no. 1, pp. 2–8, 2019.

36.

Hochreiter, “TensorFlow Core v2.7.0,” 1997. https://www.tensorflow.org/api_docs/python/tf/keras/layers/LSTM. Accessed Dec 02, 2021.

37.

Ren Y, Zhao P, Sheng Y, Yao D, Xu Z (2017) Robust softmax regression for multi-class classification with self-paced learning. IJCAI Int Jt Conf Artif Intell. https://doi.org/10.24963/ijcai.2017/368CrossRef

38.

Abadi M et al (2016) TensorFlow: large-scale machine learning on heterogeneous distributed systems. Netw Comput Neural Syst 16(2–3):121–138. https://doi.org/10.1080/09548980500300507CrossRef

39.

D. P. Kingma and J. L. Ba, “Adam: A method for stochastic optimization,” 3rd Int. Conf. Learn. Represent. ICLR 2015 - Conf. Track Proc., pp. 1–15, 2015.

40.

Janocha K, Czarnecki WM (2016) On loss functions for deep neural networks in classification. Schedae Informaticae 25:49–59. https://doi.org/10.4467/20838476SI.16.004.6185CrossRef

41.

Sokolova M, Lapalme G (2009) A systematic analysis of performance measures for classification tasks. Inf Process Manag 45(4):427–437. https://doi.org/10.1016/j.ipm.2009.03.002CrossRef

42.

A. Murad and J.-Y. Pyun, “Deep Recurrent Neural Networks for Human Activity Recognition,” 2017, doi: https://doi.org/10.3390/s17112556.

43.

L. Lu, Y. Su, and G. E. Karniadakis, “Collapse of deep and narrow neural nets,” no. 2016, pp. 1–17, 2017.

44.

H. Daneshmand, J. Kohler, F. Bach, T. Hofmann, and A. Lucchi, “Batch Normalization Provably Avoids Rank Collapse for Randomly Initialised Deep Networks,” no. NeurIPS, 2020.

45.

F. Ding, X. Luo, Y. Cai, and W. Chang, “Acceleration feedback control for enhancing dynamic stiffness of fast tool servo system considering the sensor imperfections,” Mech. Syst. Signal Process., vol. 141, no. xxxx, p. 106429, 2020, doi: https://doi.org/10.1016/j.ymssp.2019.106429.

46.

Bishop CM (1995) Training with noise is equivalent to tikhonov regularization. Neural Comput 116:108–116CrossRef

47.

Yang Z, Lu Y, Yeung H, Krishnamurty S (2019) Investigation of deep learning for real-time melt pool classification in additive manufacturing. IEEE Int. Conf. Autom. Sci. Eng. 2019:640–647. https://doi.org/10.1109/COASE.2019.8843291CrossRef

Titel: Investigation of long short-term memory networks for real-time process monitoring in fused deposition modeling
verfasst von: Ahmed Shany Khusheef
Mohammad Shahbazi
Ramin Hashemi
Publikationsdatum: 18.12.2022
Verlag: Springer International Publishing
Erschienen in: Progress in Additive Manufacturing / Ausgabe 5/2023
Print ISSN: 2363-9512
Elektronische ISSN: 2363-9520
DOI: https://doi.org/10.1007/s40964-022-00371-x

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 5/2023

Evolution of equiaxed α/β microstructure of annealed SLM-built Ti64: role of TiB2

Augmenting mechanical design engineering with additive manufacturing

Editorial PIAM November 2023

Additive manufacturing for biomedical applications: a review on classification, energy consumption, and its appreciable role since COVID-19 pandemic

Strength and fatigue behavior assessment of the SCALMALLOY® material to functionally adapt the performance of L-PBF components within CAE simulations

Standardisation efforts of ISO/TC 261 “additive manufacturing” 20th plenary meeting of ISO/TC 261 “additive manufacturing”

Premium Partner

Marktübersichten