Trained Persistent Memory for Frozen Encoder--Decoder LLMs: Six Architectural Methods

Abstract

Frozen encoder--decoder language models are stateless: the latent representation is discarded after every forward pass, so no information persists across sessions. This paper presents a proof-of-concept pilot study showing that persistent memory in the continuous latent space of a frozen LLM is feasible -- even under severe resource constraints (a single frozen Flan-T5-XL backbone, small trainable adapters, a single dataset). We implement six architectural methods spanning three injection points and four write mechanisms; unlike text-level memory systems, every write and read is a differentiable operation on dense vectors. After training only the adapter, the memory bank continues to accumulate at inference time without gradients, enabling conversational learning. Under a forgetting-curve evaluation on LoCoMo at two capacity scales (1× and 10×), the stateless baseline scores exactly zero; at 10× all six trained adapters produce positive memory-recall curves; at 1× three methods collapse, revealing capacity as a critical design parameter. Because the memory bank is a compact numerical array, it can be scaled to arbitrarily large capacity without altering the backbone. We argue that full end-to-end training with larger models, larger data, and orders-of-magnitude larger memory will yield substantially stronger results; this pilot study establishes the feasibility baseline and design-space taxonomy that such efforts require.

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