arxiv_cl 96% Match Research Paper AI Researchers,NLP Scientists,Knowledge Graph Engineers,Machine Learning Engineers 2 weeks ago

MemoTime: Memory-Augmented Temporal Knowledge Graph Enhanced Large Language Model Reasoning

large-language-models › reasoning

📄 Abstract

Abstract: Large Language Models (LLMs) have achieved impressive reasoning abilities, but struggle with temporal understanding, especially when questions involve multiple entities, compound operators, and evolving event sequences. Temporal Knowledge Graphs (TKGs), which capture vast amounts of temporal facts in a structured format, offer a reliable source for temporal reasoning. However, existing TKG-based LLM reasoning methods still struggle with four major challenges: maintaining temporal faithfulness in multi-hop reasoning, achieving multi-entity temporal synchronization, adapting retrieval to diverse temporal operators, and reusing prior reasoning experience for stability and efficiency. To address these issues, we propose MemoTime, a memory-augmented temporal knowledge graph framework that enhances LLM reasoning through structured grounding, recursive reasoning, and continual experience learning. MemoTime decomposes complex temporal questions into a hierarchical Tree of Time, enabling operator-aware reasoning that enforces monotonic timestamps and co-constrains multiple entities under unified temporal bounds. A dynamic evidence retrieval layer adaptively selects operator-specific retrieval strategies, while a self-evolving experience memory stores verified reasoning traces, toolkit decisions, and sub-question embeddings for cross-type reuse. Comprehensive experiments on multiple temporal QA benchmarks show that MemoTime achieves overall state-of-the-art results, outperforming the strong baseline by up to 24.0%. Furthermore, MemoTime enables smaller models (e.g., Qwen3-4B) to achieve reasoning performance comparable to that of GPT-4-Turbo.

Key Contributions

Proposes MemoTime, a memory-augmented TKG framework to enhance LLM temporal reasoning by addressing challenges in temporal faithfulness, multi-entity synchronization, and retrieval adaptation. It introduces structured grounding, recursive reasoning, and continual experience learning, decomposing temporal questions into a 'Tree of Time' for improved stability and efficiency.

Business Value

Enhances the ability of AI systems to understand and reason about time-sensitive information, critical for applications in finance, historical analysis, event prediction, and complex decision support systems.

Paper Metadata

Innovation Type

New Framework/Architecture

Deployment Feasibility

Moderate. Requires integration of LLMs with TKGs and a memory augmentation module, which can be complex to implement and maintain.

Limitations Addressed

LLM struggles with temporal understanding,Maintaining temporal faithfulness in multi-hop reasoning,Achieving multi-entity temporal synchronization,Adapting retrieval to diverse temporal operators,Reusing prior reasoning experience

Technical Tags

temporal reasoningknowledge graphsLLM reasoningmemory augmentationmulti-hop reasoningtemporal faithfulnessstructured groundingcontinual learning

Research Topics

LLM ReasoningKnowledge RepresentationTemporal DynamicsAI Memory SystemsInformation Integration

Methods & Architectures

Memory augmentationTemporal Knowledge Graphs (TKGs)Structured groundingRecursive reasoningContinual experience learningTree of Time decomposition Large Language Models (LLMs)Temporal Knowledge Graphs (TKGs)

Applications & Tasks

AI Reasoning Knowledge Management Temporal Data Analysis Temporal Understanding DeficienciesMulti-hop Reasoning ChallengesMulti-entity Temporal SynchronizationRetrieval AdaptationReasoning Stability Temporal Question AnsweringComplex Event ReasoningLLM Reasoning Enhancement

Related Fields

Artificial IntelligenceKnowledge Representation and ReasoningNatural Language ProcessingDatabasesMachine Learning

Keywords

LLMtemporal reasoningknowledge graphTKGmemoryreasoningmulti-hoptemporalAINLPstructured groundingcontinual learning

Academic Context

#LLM Reasoning#Knowledge Representation#Temporal Dynamics#AI Memory Systems#Information Integration

Commercial Potential

Potential Products

Advanced AI assistants for temporal analysisKnowledge management systems with temporal reasoning

Target Industries

FinanceHistoryEvent ManagementResearchIntelligence

Use Case Examples

Answering complex historical event timelinesPredicting future event sequences based on past dataAnalyzing financial market trends over time

Competitive Edge

Addresses specific limitations in LLM temporal reasoning by integrating structured knowledge from TKGs with memory augmentation, offering a more robust approach than standalone LLMs or basic TKG integration.

Market Opportunity

Growing demand for AI that can understand complex temporal relationships.

Revenue Models

Licensing of the MemoTime frameworkspecialized AI services.

Resource Requirements

Compute Needs

High, due to LLM inference and TKG processing.

Data Requirements

Requires structured temporal knowledge graphs and relevant query data.

Deployment Constraints

Integration complexity, potential latency issues.

Scalability

Scalability depends on the efficiency of TKG construction, retrieval, and LLM inference, as well as the memory augmentation mechanism.

Regulatory Considerations

None explicitly mentioned.

Production Readiness

Maturity Level

Research/Development

Time to Market

1-3 years for robust productization.

Patent Potential

Moderate, for novel framework components and integration methods.

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