Abstract
High velocity oxygen fuel (HVOF) spraying is used to create protective coating layers on workpieces to achieve specific surface properties.
Given the process parameters and a fixed coating material, the resulting coating properties can be accurately predicted using machine learning algorithms.
However, since the coating material strongly influences the outcome, it is unclear how well a model trained on one specific coating material can predict properties for a different material.
In this work, we demonstrate that significant differences in the marginal distributions between coating materials make direct application of existing models challenging.
We present several transfer learning approaches to adapt existing models to new coating materials.
Our results show that simple methods, such as linear residual models, are already sufficient to achieve accurate adaptation, drastically reducing the experimental effort for new materials and preserving knowledge from the original model.
Furthermore, for symbolic regression models, we show that re-optimizing numeric coefficients is an effective and computationally efficient strategy that also maintains model interpretability.
Given the process parameters and a fixed coating material, the resulting coating properties can be accurately predicted using machine learning algorithms.
However, since the coating material strongly influences the outcome, it is unclear how well a model trained on one specific coating material can predict properties for a different material.
In this work, we demonstrate that significant differences in the marginal distributions between coating materials make direct application of existing models challenging.
We present several transfer learning approaches to adapt existing models to new coating materials.
Our results show that simple methods, such as linear residual models, are already sufficient to achieve accurate adaptation, drastically reducing the experimental effort for new materials and preserving knowledge from the original model.
Furthermore, for symbolic regression models, we show that re-optimizing numeric coefficients is an effective and computationally efficient strategy that also maintains model interpretability.
| Original language | English (American) |
|---|---|
| Publication status | Accepted/In press - Nov 2025 |
| Event | International Conference on Industry of the Future and Smart Manufacturing - , Malta Duration: 12 Nov 2025 → 14 Nov 2025 |
Conference
| Conference | International Conference on Industry of the Future and Smart Manufacturing |
|---|---|
| Abbreviated title | ISM 2025 |
| Country/Territory | Malta |
| Period | 12.11.2025 → 14.11.2025 |
Keywords
- Interpretable Machine Learning
- Transfer Learning
- Model Adaptation
- Symbolic Regression
- Thermal Spraying