Degradation Modeling and Prognostic Analysis Under Unknown Failure Modes

The proposed method can be applied to other complex systems beyond aircraft engines by adapting the framework to suit the specific characteristics and requirements of different systems. For example, in automotive systems, the sensor signals and degradation patterns may differ from those in aircraft engines. By adjusting the input data preprocessing steps and model architecture, the same approach can be used to identify failure modes and predict RUL for automotive components like transmissions or suspension systems. Additionally, in manufacturing environments, where machines undergo wear and tear over time, this method can be utilized to monitor equipment health and schedule maintenance proactively. By customizing the feature selection process and training models on relevant sensor data, manufacturers can optimize their operations by predicting failures before they occur.

While UMAP dimension reduction is a powerful tool for visualizing high-dimensional datasets and capturing complex relationships between variables, there are potential limitations when using it for failure mode identification: Sensitivity to hyperparameters: The performance of UMAP is highly dependent on parameters such as the number of nearest neighbors (k) and minimum distance (min dist). Selecting optimal values for these parameters can be challenging. Interpretability: While UMAP provides low-dimensional representations of data points, interpreting these representations in terms of underlying physical mechanisms or failure modes may not always be straightforward. Scalability: UMAP may face scalability issues when dealing with very large datasets due to its computational complexity. Overfitting: There is a risk of overfitting when applying UMAP if not carefully tuned or validated on unseen data.

Incorporating domain knowledge into RUL prediction models can have several impacts on overall system reliability: Improved accuracy: Domain-specific insights about how components degrade over time can help refine predictive models leading to more accurate RUL estimates. Early fault detection: By integrating domain expertise into prognostic models, potential faults or degradation patterns that might go unnoticed by purely data-driven approaches could be identified earlier. Enhanced decision-making: Having domain knowledge incorporated into RUL predictions allows operators to make informed decisions regarding maintenance schedules, part replacements, or operational adjustments based on predicted remaining useful life. Increased system reliability: Utilizing domain knowledge ensures that predictions align with known degradation mechanisms within a system which ultimately contributes towards enhancing overall system reliability through proactive maintenance strategies tailored specifically for each component's behavior under various conditions.