Uhgeval: Benchmarking The Hallucination Of Chinese Large Language Models Via Unconstrained Generation · The Large Language Model Bible Contribute to LLM-Bible

Uhgeval: Benchmarking The Hallucination Of Chinese Large Language Models Via Unconstrained Generation

Liang Xun, Song Shichao, Niu Simin, Li Zhiyu, Xiong Feiyu, Tang Bo, Wang Yezhaohui, He Dawei, Cheng Peng, Wang Zhonghao, Deng Haiying. Arxiv 2023

[Paper]    
Applications GPT Language Modeling Model Architecture Reinforcement Learning Tools

Large language models (LLMs) have emerged as pivotal contributors in contemporary natural language processing and are increasingly being applied across a diverse range of industries. However, these large-scale probabilistic statistical models cannot currently ensure the requisite quality in professional content generation. These models often produce hallucinated text, compromising their practical utility in professional contexts. To assess the authentic reliability of LLMs in text generation, numerous initiatives have developed benchmark evaluations for hallucination phenomena. Nevertheless, these benchmarks frequently utilize constrained generation techniques due to cost and temporal constraints. These techniques encompass the use of directed hallucination induction and strategies that deliberately alter authentic text to produce hallucinations. These approaches are not congruent with the unrestricted text generation demanded by real-world applications. Furthermore, a well-established Chinese-language dataset dedicated to the evaluation of hallucinations in text generation is presently lacking. Consequently, we have developed an Unconstrained Hallucination Generation Evaluation (UHGEval) benchmark, designed to compile outputs produced with minimal restrictions by LLMs. Concurrently, we have established a comprehensive benchmark evaluation framework to aid subsequent researchers in undertaking scalable and reproducible experiments. We have also executed extensive experiments, evaluating prominent Chinese language models and the GPT series models to derive professional performance insights regarding hallucination challenges.

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