RAN Cortex: Memory-Augmented Intelligence for Context-Aware Decision-Making in AI-Native Networks

TL;DR

RAN Cortex introduces a memory-augmented architecture for AI-native Radio Access Networks, enabling context-aware decision-making that improves adaptability and continuity in dynamic network environments.

Contribution

It proposes a modular memory-augmented system architecture for RAN AI agents, formalizes the retrieval-augmented decision problem, and demonstrates practical use cases.

Findings

Enhanced decision adaptability in RAN scenarios

Improved network management through contextual recall

Framework enabling learning agents without retraining

Abstract

As Radio Access Networks (RAN) evolve toward AI-native architectures, intelligent modules such as xApps and rApps are expected to make increasingly autonomous decisions across scheduling, mobility, and resource management domains. However, these agents remain fundamentally stateless, treating each decision as isolated, lacking any persistent memory of prior events or outcomes. This reactive behavior constrains optimization, especially in environments where network dynamics exhibit episodic or recurring patterns. In this work, we propose RAN Cortex, a memory-augmented architecture that enables contextual recall in AI-based RAN decision systems. RAN Cortex introduces a modular layer composed of four elements: a context encoder that transforms network state into high-dimensional embeddings, a vector-based memory store of past network episodes, a recall engine to retrieve semantically similar situations, and a policy interface that supplies historical context to AI agents in real time or near-real time. We formalize the retrieval-augmented decision problem in the RAN, present a system architecture compatible with O-RAN interfaces, and analyze feasible deployments within the Non-RT and Near-RT RIC domains. Through illustrative use cases such as stadium traffic mitigation and mobility management in drone corridors, we demonstrate how contextual memory improves adaptability, continuity, and overall RAN intelligence. This work introduces memory as a missing primitive in AI-native RAN designs and provides a framework to enable "learning agents" without the need for retraining or centralized inference