Unraveling and Mitigating Retriever Inconsistencies in Retrieval-Augmented Large Language Models for Open-Domain Question Answering

The EoR framework, while designed for single-hop short-form ODQA, can be adapted for more complex scenarios like multi-hop reasoning or long-form answers by focusing on two key aspects: Enhancing the Voting Mechanism: Sophisticated Similarity Metrics: Instead of relying on simple metrics like EM or BERTscore, incorporate measures specifically designed for long-form text comparison, such as: Semantic Text Similarity (STS): Capture deeper semantic relations between long answer candidates. Question-Answer Entailment: Determine if one answer candidate better entails the question's intent compared to others. Coherence and Fluency Scoring: Evaluate the internal consistency and readability of generated long-form answers. Hierarchical Voting: For multi-hop reasoning, implement a staged voting process. Initially, assess retrieved evidence snippets for each reasoning step. Subsequently, evaluate the overall coherence and accuracy of the combined, multi-hop answer. Training with Complex Data and Evaluation: Multi-hop and Long-Form Datasets: Train EoR on datasets specifically designed for these complex scenarios. Examples include HotpotQA (for multi-hop reasoning) or ELI5 (for long-form explanations). Human Evaluation: Given the subjectivity of complex QA, incorporate human judgments for training and evaluation. This could involve assessing answer completeness, reasoning soundness, or factuality. By adapting the voting mechanism and training paradigm, EoR can effectively address the challenges posed by multi-hop reasoning and long-form answer generation in complex QA tasks.

Yes, using multiple retrievers in EoR can increase computational costs, especially with many queries. However, several optimization strategies can mitigate this: Efficient Retriever Implementations: Prioritize fast retrievers: Opt for retrievers known for speed, such as those based on inverted indexes or approximate nearest neighbor search. Parallelization: Execute retrievals concurrently to significantly reduce latency, especially when dealing with a large retriever pool. Batch Inference with LLMs: Shared Reader Model: As highlighted in the paper, EoR benefits from the shared reader model, allowing batch inference for generating answers from different retrievals. This amortizes the cost of LLM inference. Dynamic Retriever Selection: Adaptive Retrieval: Instead of using all retrievers for every query, dynamically select a subset based on query characteristics or early indicators of retrieval difficulty. Cascading Retrievers: Employ a staged approach where computationally cheaper retrievers are used first, and more expensive ones are only triggered if initial retrieval confidence is low. Offline Pre-computation: Pre-computed Embeddings: For retrievers relying on semantic similarity, pre-compute document embeddings to speed up retrieval during inference. By implementing these optimizations, the computational overhead of EoR can be effectively managed, making it scalable for handling large-scale question answering applications.

You are right, inconsistencies can arise from the inherent ambiguity and subjectivity of natural language, even with EoR mitigating retriever and reader model inconsistencies. Here's how to address this: Embrace Answer Diversity: Instead of forcing a single "correct" answer: Acknowledge that multiple valid interpretations or perspectives might exist, especially for open-ended or subjective questions. Present multiple high-scoring answers: EoR can be adapted to return a ranked list of diverse answers, reflecting different facets of the question or varying levels of confidence. Incorporate Context and User Modeling: User-specific preferences: Learn and apply user preferences for answer style, length, or level of detail to tailor responses and reduce perceived inconsistency. Dialogue History: In conversational settings, maintain context and track previous turns to resolve ambiguities and ensure consistent interpretation across interactions. Explicitly Model Uncertainty: Confidence Scores: Provide confidence estimates alongside answers, indicating the system's certainty in its interpretation and response. Hedging Strategies: Use linguistic hedges (e.g., "it is likely," "based on the available information") to acknowledge uncertainty and avoid presenting potentially subjective interpretations as definitive facts. Human-in-the-Loop for Refinement: Active Learning: Identify instances where the system is uncertain or where multiple valid interpretations exist. Route these cases for human review and annotation to improve the system's handling of ambiguity. By acknowledging the inherent subjectivity of language and incorporating mechanisms for handling ambiguity, EoR can be extended to provide more nuanced, transparent, and user-centric answers, even in the face of linguistic complexities.