Congratulations to Jiang Xiyuan, Su Ziqing, and Feng Yixiao on successfully defending their Tsinghua University Master’s theses!
Jiang Xiyuan's thesis is titled "Rapid Prediction of Jacket Structural Mechanical Response Based on MultiGraph Fusion Network." Focusing on the rapid prediction of jacket mechanical responses, this study abstracts the structure into a multi-dimensional topological graph system and constructs a multi-graph fusion prediction model combining graph neural networks and multilayer perceptrons, enabling the joint learning of marine environmental parameters and structural features. For ultra-large deepwater jackets, a hierarchical graph modeling approach based on local topology is proposed to reduce learning complexity, and an intelligent design platform is developed. This research provides new insights for the efficient analysis and lifecycle intelligent management of offshore engineering structures.
Su Ziqing's thesis is titled "Research on the Abnormal Early Warning of Operation Progress for Cross-Sea Bridges Based on Enhanced Knowledge Graph." This study introduces knowledge graph and ontology engineering technologies to investigate intelligent monitoring and anomaly warning technologies for cross-sea bridge operation progress, with a particular focus on the semantic fusion of multi-source heterogeneous data. Lightweight detection and few-shot learning algorithms are utilized for visual element perception, and automated recognition of operation behaviors is achieved through spatial coupling degree analysis. Meanwhile, a progress warning strategy is established based on the constructed ontology model and dynamic knowledge graph, promoting the transformation of cross-sea bridge operations from “passive response” to “active warning” and “intelligent decision-making”.
Feng Yixiao's thesis is titled "Multibody Dynamics-Based Adaptive Task Scheduling Method for Smart Cities." Addressing the real-time scheduling challenges in smart city edge computing, this study proposes an adaptive task scheduling method based on multibody dynamics principles. By constructing a cloud–edge–device collaborative evaluation model and designing physical field mapping and rigid-body dynamics evolution mechanisms, tasks and resources are mapped into virtual entities to achieve self-organized scheduling in dynamic environments. A grid index is introduced to reduce computational overhead, and a simulation platform is built using real data and a physics engine for validation. This method offers an efficient, robust, and low-overhead solution for real-time resource management in large-scale heterogeneous edge networks. Notably, this thesis was awarded the title of Outstanding Master’s Thesis of Tsinghua University.