Computational Intelligence Approaches to Defect Detection in 3D Printing

Digitalization in smart manufacturing is driving the use of Internet of Things (IoT) in many 3D printing environments. These sensors facilitate collection of data in the form of time series that can reflect a normal condition or faulty state. The ability to identify the normal conditions or faulty s...

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Published in2025 IEEE Symposium on Computational Intelligence on Engineering/Cyber Physical Systems (CIES) pp. 1 - 7
Main Authors Awonuga, Oluwaseun, Madden, Kyle, Coleman, Sonya, Kerr, Dermot, Quinn, Justin
Format Conference Proceeding
LanguageEnglish
Published IEEE 17.03.2025
Subjects
3D printing
Computational intelligence
Computational modeling
correlation
defect
Defect detection
Intelligent sensors
sensor
Solid modeling
Subtraction techniques
Temperature distribution
Temperature sensors
Three-dimensional printing
Time series analysis
unsupervised methods
Online AccessGet full text
DOI10.1109/CIES64955.2025.11007634

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Abstract Digitalization in smart manufacturing is driving the use of Internet of Things (IoT) in many 3D printing environments. These sensors facilitate collection of data in the form of time series that can reflect a normal condition or faulty state. The ability to identify the normal conditions or faulty states by analysing sensor data is vital to minimise defects in additive manufacturing processes. However, detecting a defect based on correlated behaviour of multiple sensors is complex and an active area of ongoing research utilising multivariate time series. Currently, no comparative studies exist between machine learning and deep learning approaches that consider the potential correlation between multiple sensor data while constructing a fault detection model. In this work, we propose a unique computational intelligence approach to defect detection in a multi-sensor fused deposition modelling 3D printer. We decompose temperature and humidity sensor data into residual components using a seasonal-trend procedure with locally estimated scatterplot smoothing. A subtraction technique is then utilised to reduce two time series into one, by focusing directly on a "deviation from correlated behavior" of both sensor data. Five unsupervised models were used to detect defective state using the joint feature of temperature and humidity as training data. The test results demonstrated that Long Short-Term Memory-AutoEncoder outperformed other models with a recall rate of 94% in identifying all possible defects from the correlated behaviour of the sensors during print activity.
AbstractList Digitalization in smart manufacturing is driving the use of Internet of Things (IoT) in many 3D printing environments. These sensors facilitate collection of data in the form of time series that can reflect a normal condition or faulty state. The ability to identify the normal conditions or faulty states by analysing sensor data is vital to minimise defects in additive manufacturing processes. However, detecting a defect based on correlated behaviour of multiple sensors is complex and an active area of ongoing research utilising multivariate time series. Currently, no comparative studies exist between machine learning and deep learning approaches that consider the potential correlation between multiple sensor data while constructing a fault detection model. In this work, we propose a unique computational intelligence approach to defect detection in a multi-sensor fused deposition modelling 3D printer. We decompose temperature and humidity sensor data into residual components using a seasonal-trend procedure with locally estimated scatterplot smoothing. A subtraction technique is then utilised to reduce two time series into one, by focusing directly on a "deviation from correlated behavior" of both sensor data. Five unsupervised models were used to detect defective state using the joint feature of temperature and humidity as training data. The test results demonstrated that Long Short-Term Memory-AutoEncoder outperformed other models with a recall rate of 94% in identifying all possible defects from the correlated behaviour of the sensors during print activity.
Author Kerr, Dermot
Madden, Kyle
Awonuga, Oluwaseun
Quinn, Justin
Coleman, Sonya
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  organization: Ulster University,SCEIS,Derry,United Kingdom
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SubjectTerms 3D printing
Computational intelligence
Computational modeling
correlation
defect
Defect detection
Intelligent sensors
sensor
Solid modeling
Subtraction techniques
Temperature distribution
Temperature sensors
Three-dimensional printing
Time series analysis
unsupervised methods
Title Computational Intelligence Approaches to Defect Detection in 3D Printing
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