English

MEMSAD: Gradient-Coupled Anomaly Detection for Memory Poisoning in Retrieval-Augmented Agents

Cryptography and Security 2026-05-08 v2 Artificial Intelligence Machine Learning

Abstract

Persistent external memory enables LLM agents to maintain context across sessions, yet its security properties remain formally uncharacterized. We formalize memory poisoning attacks on retrieval-augmented agents as a Stackelberg game with a unified evaluation framework spanning three attack classes with escalating access assumptions. Correcting an evaluation protocol inconsistency in the triggered-query specification of Chen et al. (2024), we show faithful evaluation increases measured attack success by 4×4\times (ASR-R: 0.251.000.25 \to 1.00). Our primary contribution is MEMSAD (Semantic Anomaly Detection), a calibration-based defense grounded in a gradient coupling theorem: under encoder regularity, the anomaly score gradient and the retrieval objective gradient are provably identical, so any continuous perturbation that reduces detection risk necessarily degrades retrieval rank. This coupling yields a certified detection radius guaranteeing correct classification regardless of adversary strategy. We prove minimax optimality via Le Cam's method, showing any threshold detector requires Ω(1/ρ2)\Omega(1/\rho^2) calibration samples and MEMSAD achieves this up to log(1/δ)\log(1/\delta) factors. We further derive online regret bounds for rolling calibration at rate O(σ2/3Δ1/3)O(\sigma^{2/3}\Delta^{1/3}), and formally characterize a discrete synonym-invariance loophole that marks the boundary of what continuous-space defenses can guarantee. Experiments on a 3×53 \times 5 attack-defense matrix with bootstrap confidence intervals, Bonferroni-corrected hypothesis tests, and Clopper-Pearson validation (n=1,000n=1{,}000) confirm: composite defenses achieve TPR =1.00= 1.00, FPR =0.00= 0.00 across all attacks, while synonym substitution evades detection at Δ\Delta ASR-R 0\approx 0, exposing a gap existing embedding-based defenses cannot close.

Keywords

Cite

@article{arxiv.2605.03482,
  title  = {MEMSAD: Gradient-Coupled Anomaly Detection for Memory Poisoning in Retrieval-Augmented Agents},
  author = {Ishrith Gowda},
  journal= {arXiv preprint arXiv:2605.03482},
  year   = {2026}
}

Comments

28 pages, 9 figures, 6 theorems. Submitted to NeurIPS 2026

R2 v1 2026-07-01T12:50:26.291Z