TY - GEN
T1 - ACCURATE AND FAST ANOMALY DETECTION IN ADDITIVE COMPOSITE-BASED MANUFACTURING USING THERMAL CAMERAS
AU - Pike, Jay
AU - O'Brien, Chris
AU - Bailey, Benjamin
AU - Bisson, Wesley
AU - Stevens, Jason
AU - Tomlinson, Scott
AU - Studer, Gregory
AU - Villez, Kris
N1 - Publisher Copyright:
© 2025 Soc. for the Advancement of Material and Process Engineering. All rights reserved.
PY - 2025
Y1 - 2025
N2 - Today, large-scale additive manufacturing with plastics and composite materials requires continuous monitoring by experienced staff to prevent, detect and correct anomalous events affecting the performance of the printed part. We address the complexity of this demanding task by designing a camera-based anomaly detection system utilizing probabilistic principal component analysis (PPCA). This is a machine learning technique is trained with thermal images collected during normal operation of the large-scale printer (Cincinnati BAAM). This technique is advantageous for practical applications as there is no need to artificially introduce anomalous conditions into model training. During deployment, we challenge this model by introducing deliberate variations of the extruder speed. We reduce extrusion speed to a lower level, between 70 and 95% of the nominal value to collected test images. Our results show that images are easily identified as anomalous for extruder speeds at or below 85% of the nominal speed, meaning that an anomalous reduction of the material deposition rate can be detected within seconds of its onset. We show that our results are robust to (a) camera-to-camera variability and (b) print-to-print variability.
AB - Today, large-scale additive manufacturing with plastics and composite materials requires continuous monitoring by experienced staff to prevent, detect and correct anomalous events affecting the performance of the printed part. We address the complexity of this demanding task by designing a camera-based anomaly detection system utilizing probabilistic principal component analysis (PPCA). This is a machine learning technique is trained with thermal images collected during normal operation of the large-scale printer (Cincinnati BAAM). This technique is advantageous for practical applications as there is no need to artificially introduce anomalous conditions into model training. During deployment, we challenge this model by introducing deliberate variations of the extruder speed. We reduce extrusion speed to a lower level, between 70 and 95% of the nominal value to collected test images. Our results show that images are easily identified as anomalous for extruder speeds at or below 85% of the nominal speed, meaning that an anomalous reduction of the material deposition rate can be detected within seconds of its onset. We show that our results are robust to (a) camera-to-camera variability and (b) print-to-print variability.
KW - borne qualification
KW - fault detection
KW - large-format additive manufacturing
KW - statistical process control
UR - https://www.scopus.com/pages/publications/105009695475
U2 - 10.33599/nasampe/s.25.0260
DO - 10.33599/nasampe/s.25.0260
M3 - Conference contribution
AN - SCOPUS:105009695475
T3 - International SAMPE Technical Conference
SP - 85
BT - SAMPE 2025 Conference and Exhibition
PB - Soc. for the Advancement of Material and Process Engineering
T2 - SAMPE 2025 Conference and Exhibition
Y2 - 19 May 2025 through 22 May 2025
ER -