A Novel Architecture for Symbolic Reasoning with Decision Trees and LLM Agents
This addresses the problem of interpretable and robust neuro-symbolic reasoning for applications like clinical decision support and scientific discovery, though it appears incremental in building on prior hybrid approaches.
The paper tackles the challenge of integrating symbolic and neural reasoning by proposing a hybrid architecture that combines decision trees with LLM agents, achieving improvements such as +7.2% entailment consistency on ProofWriter and +5.3% accuracy gains on GSM8k.
We propose a hybrid architecture that integrates decision tree-based symbolic reasoning with the generative capabilities of large language models (LLMs) within a coordinated multi-agent framework. Unlike prior approaches that loosely couple symbolic and neural modules, our design embeds decision trees and random forests as callable oracles within a unified reasoning system. Tree-based modules enable interpretable rule inference and causal logic, while LLM agents handle abductive reasoning, generalization, and interactive planning. A central orchestrator maintains belief state consistency and mediates communication across agents and external tools, enabling reasoning over both structured and unstructured inputs. The system achieves strong performance on reasoning benchmarks. On \textit{ProofWriter}, it improves entailment consistency by +7.2\% through logic-grounded tree validation. On GSM8k, it achieves +5.3\% accuracy gains in multistep mathematical problems via symbolic augmentation. On \textit{ARC}, it boosts abstraction accuracy by +6.0\% through integration of symbolic oracles. Applications in clinical decision support and scientific discovery show how the system encodes domain rules symbolically while leveraging LLMs for contextual inference and hypothesis generation. This architecture offers a robust, interpretable, and extensible solution for general-purpose neuro-symbolic reasoning.