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Main Authors: Jhajj, Gaganpreet, Lin, Fuhua
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.01890
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author Jhajj, Gaganpreet
Lin, Fuhua
author_facet Jhajj, Gaganpreet
Lin, Fuhua
contents Knowledge graphs (KGs) require continual updates as new information emerges, but neural embedding models suffer from catastrophic forgetting when learning new tasks sequentially. We evaluate Elastic Weight Consolidation (EWC), a regularization-based continual learning method, on KG link prediction using TransE embeddings on FB15k-237. Across multiple experiments with five random seeds, we find that EWC reduces catastrophic forgetting from 12.62% to 6.85%, a 45.7% reduction compared to naive sequential training. We observe that the task partitioning strategy affects the magnitude of forgetting: relation-based partitioning (grouping triples by relation type) exhibits 9.8 percentage points higher forgetting than randomly partitioned tasks (12.62% vs 2.81%), suggesting that task construction influences evaluation outcomes. While focused on a single embedding model and dataset, our results demonstrate that EWC effectively mitigates catastrophic forgetting in KG continual learning and highlight the importance of evaluation protocol design.
format Preprint
id arxiv_https___arxiv_org_abs_2512_01890
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Elastic Weight Consolidation for Knowledge Graph Continual Learning: An Empirical Evaluation
Jhajj, Gaganpreet
Lin, Fuhua
Machine Learning
Knowledge graphs (KGs) require continual updates as new information emerges, but neural embedding models suffer from catastrophic forgetting when learning new tasks sequentially. We evaluate Elastic Weight Consolidation (EWC), a regularization-based continual learning method, on KG link prediction using TransE embeddings on FB15k-237. Across multiple experiments with five random seeds, we find that EWC reduces catastrophic forgetting from 12.62% to 6.85%, a 45.7% reduction compared to naive sequential training. We observe that the task partitioning strategy affects the magnitude of forgetting: relation-based partitioning (grouping triples by relation type) exhibits 9.8 percentage points higher forgetting than randomly partitioned tasks (12.62% vs 2.81%), suggesting that task construction influences evaluation outcomes. While focused on a single embedding model and dataset, our results demonstrate that EWC effectively mitigates catastrophic forgetting in KG continual learning and highlight the importance of evaluation protocol design.
title Elastic Weight Consolidation for Knowledge Graph Continual Learning: An Empirical Evaluation
topic Machine Learning
url https://arxiv.org/abs/2512.01890