When Words Predict Workload

Abstract

Standard distributed llm schedulers rely on static token counts or rolling latency averages, making them susceptible to failures on statutorily constrained text. On epo claims governed by Article 84 epc, linguistic rigidity makes human and machine authorship statistically indistinguishable. Resolving this ambiguity mid-flight forces dynamic multi-model ensemble expansion, triggering unpredictable KV-cache and weight-allocation spikes that saturate consumer-grade edge GPU VRAM and cause severe oom crashes. To prevent hardware collapse, we propose a CPU-side Linguistic Resource Forecasting (LRF) gateway. The gateway extracts a 16-dimensional text-structure vector and applies an XGBoost predictor to forecast trap-band membership. The resulting escalation probability () is evaluated against a dynamic, closed-form routing threshold ((t)) computed via real-time latency telemetry. Requests are safely routed to either a local Qwen2.5-7B edge worker or a remote contrastive ensemble (Qwen2.5 7B + 32B) on an NVIDIA H100 before any edge GPU memory is allocated. In a 6,000-request live trial, the LRF gateway reduced the operational misroute fraction (Rmis) to 0.087--0.095, an order of magnitude below the token-count baseline (0.849). Peak edge VRAM remained safely bounded at 4.82 (under the 8 ceiling) across a 27× variation in wan delay. The predictor achieved a live-trial AUROC of 0.84, and the dynamic (t) controller yielded an 8.2\% relative reduction in misroutes compared to an equivalent static threshold.

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