unrelated knowledge
Disentangling Knowledge Representations for Large Language Model Editing
Zhang, Mengqi, Zhou, Zisheng, Ye, Xiaotian, Liu, Qiang, Ren, Zhaochun, Chen, Zhumin, Ren, Pengjie
Knowledge Editing has emerged as a promising solution for efficiently updating embedded knowledge in large language models (LLMs). While existing approaches demonstrate effectiveness in integrating new knowledge and preserving the original capabilities of LLMs, they fail to maintain fine-grained irrelevant knowledge facts that share the same subject as edited knowledge but differ in relation and object. This challenge arises because subject representations inherently encode multiple attributes, causing the target and fine-grained irrelevant knowledge to become entangled in the representation space, and thus vulnerable to unintended alterations during editing. To address this, we propose DiKE, a novel approach that Disentangles Knowledge representations for LLM Editing (DiKE). DiKE consists of two key components: a Knowledge Representation Disentanglement (KRD) module that decomposes the subject representation into target-knowledgerelated and -unrelated components, and a Disentanglement-based Knowledge Edit (DKE) module that updates only the target-related component while explicitly preserving the unrelated one. We further derive a closed-form, rank-one parameter update based on matrix theory to enable efficient and minimally invasive edits. To rigorously evaluate fine-grained irrelevant knowledge preservation, we construct FINE-KED, a new benchmark comprising fine-grained irrelevant knowledge at different levels of relational similarity to the edited knowledge. Extensive experiments across multiple LLMs demonstrate that DiKE substantially improves fine-grained irrelevant knowledge preservation while maintaining competitive general editing performance.
Editing Factual Knowledge and Explanatory Ability of Medical Large Language Models
Xu, Derong, Zhang, Ziheng, Zhu, Zhihong, Lin, Zhenxi, Liu, Qidong, Wu, Xian, Xu, Tong, Wang, Wanyu, Ye, Yuyang, Zhao, Xiangyu, Zheng, Yefeng, Chen, Enhong
Model editing aims to precisely alter the behaviors of large language models (LLMs) in relation to specific knowledge, while leaving unrelated knowledge intact. This approach has proven effective in addressing issues of hallucination and outdated information in LLMs. However, the potential of using model editing to modify knowledge in the medical field remains largely unexplored, even though resolving hallucination is a pressing need in this area. Our observations indicate that current methods face significant challenges in dealing with specialized and complex knowledge in medical domain. Therefore, we propose MedLaSA, a novel Layer-wise Scalable Adapter strategy for medical model editing. MedLaSA harnesses the strengths of both adding extra parameters and locate-then-edit methods for medical model editing. We utilize causal tracing to identify the association of knowledge in neurons across different layers, and generate a corresponding scale set from the association value for each piece of knowledge. Subsequently, we incorporate scalable adapters into the dense layers of LLMs. These adapters are assigned scaling values based on the corresponding specific knowledge, which allows for the adjustment of the adapter's weight and rank. The more similar the content, the more consistent the scale between them. This ensures precise editing of semantically identical knowledge while avoiding impact on unrelated knowledge. To evaluate the editing impact on the behaviours of LLMs, we propose two model editing studies for medical domain: (1) editing factual knowledge for medical specialization and (2) editing the explanatory ability for complex knowledge. We build two novel medical benchmarking datasets and introduce a series of challenging and comprehensive metrics. Extensive experiments on medical LLMs demonstrate the editing efficiency of MedLaSA, without affecting unrelated knowledge.
Eva-KELLM: A New Benchmark for Evaluating Knowledge Editing of LLMs
Wu, Suhang, Peng, Minlong, Chen, Yue, Su, Jinsong, Sun, Mingming
Large language models (LLMs) possess a wealth of knowledge encoded in their parameters. However, this knowledge may become outdated or unsuitable over time. As a result, there has been a growing interest in knowledge editing for LLMs and evaluating its effectiveness. Existing studies primarily focus on knowledge editing using factual triplets, which not only incur high costs for collection but also struggle to express complex facts. Furthermore, these studies are often limited in their evaluation perspectives. In this paper, we propose Eva-KELLM, a new benchmark for evaluating knowledge editing of LLMs. This benchmark includes an evaluation framework and a corresponding dataset. Under our framework, we first ask the LLM to perform knowledge editing using raw documents, which provides a more convenient and universal approach compared to using factual triplets. We then evaluate the updated LLM from multiple perspectives. In addition to assessing the effectiveness of knowledge editing and the retention of unrelated knowledge from conventional studies, we further test the LLM's ability in two aspects: 1) Reasoning with the altered knowledge, aiming for the LLM to genuinely learn the altered knowledge instead of simply memorizing it. 2) Cross-lingual knowledge transfer, where the LLM updated with raw documents in one language should be capable of handling queries from another language. To facilitate further research, we construct and release the corresponding dataset. Using this benchmark, we investigate the effectiveness of several commonly-used knowledge editing methods. Experimental results indicate that the current methods for knowledge editing using raw documents are not effective in yielding satisfactory results, particularly when it comes to reasoning with altered knowledge and cross-lingual knowledge transfer.