Physics-Informed Machine Learning for Seismic Response Prediction of Nonlinear Steel Moment Resisting Frame Structures

The Physics-Informed Machine Learning (PiML) method proposed in the context can be extended to various types of structures beyond steel moment resisting frames by adapting the model architecture and training data. The key lies in incorporating scientific principles and physical laws specific to the new type of structure into the deep neural networks used for modeling. For instance, if considering concrete structures, additional material properties such as compressive strength, tensile strength, and elastic modulus would need to be integrated into the model. Similarly, for wooden structures, parameters like grain orientation and moisture content could play a significant role. Furthermore, different structural elements unique to each type of structure should be accounted for in the input data. This may include beam-column joints for reinforced concrete frames or shear walls for tall buildings. By adjusting the input features and constraints based on these specific characteristics, the PiML method can effectively predict seismic responses or other dynamic behaviors across a wide range of structural systems.

Purely data-driven approaches in structural metamodeling have several limitations that need to be considered: Limited Generalizability: Data-driven models rely heavily on existing datasets for training. If these datasets do not encompass all possible scenarios or variations within a system, there is a risk that the model may not generalize well to unseen conditions. Lack of Interpretability: Black-box nature: Data-driven models often lack interpretability due to their complex architectures and high dimensionality. Data Dependency: These models require large amounts of high-quality data for effective training which might not always be readily available. Overfitting: Without proper regularization techniques or validation strategies, data-driven models are susceptible to overfitting on noisy training data leading to poor performance on unseen test sets. Incorporating Physical Constraints: Purely data-driven methods may struggle with enforcing physical constraints inherent in engineering problems unless explicitly programmed into them.

Hybrid modeling techniques aim at combining both physics-based knowledge and empirical insights from available data sources: Feature Engineering: Hybrid models leverage domain knowledge about relevant features that influence system behavior while also learning from raw input signals through machine learning algorithms. Physics-Informed Regularization: By integrating physical laws as constraints during model training (as seen in PiML), hybrid models ensure that predictions align with known scientific principles while benefiting from ML's flexibility. 3Interpretability vs Complexity Trade-off: Hybrid models strike a balance between interpretability derived from physics-based rules and complexity captured by sophisticated ML algorithms ensuring both accuracy and explainability 4Handling Uncertainties: Hybrid approaches excel at handling uncertainties present in real-world engineering applications by combining deterministic physics-based calculations with probabilistic outputs generated through machine learning techniques By blending these two methodologies effectively, hybrid modeling offers robustness against limited datasets while maintaining fidelity towards underlying physical phenomena prevalent in engineering systems