Per-Axis Weight Deltas for Frequent Model Updates
This addresses storage and cold-start latency issues for serving many task-specialized LLM variants, representing an incremental improvement over existing delta compression methods.
The paper tackles the problem of high storage and latency from fine-tuned LLM checkpoints by proposing a 1-bit delta compression scheme with per-axis scaling, which reduces artifacts to several times smaller than full FP16 checkpoints while improving reconstruction quality.
Serving many task-specialized LLM variants is often limited by the large size of fine-tuned checkpoints and the resulting cold-start latency. Since fine-tuned weights differ from their base model by relatively small structured residuals, a natural approach is to represent them as compressed deltas. We propose a simple 1-bit delta scheme that stores only the sign of the weight difference together with lightweight per-axis (row/column) FP16 scaling factors, learned from a small calibration set. This design preserves the compactness of 1-bit deltas while more accurately capturing variation across weight dimensions, leading to improved reconstruction quality over scalar alternatives. From a systems perspective, a streamlined loader that transfers packed deltas in a single operation per module reduces cold-start latency and storage overhead, with artifacts several times smaller than a full FP16 checkpoint. The method is drop-in, requires minimal calibration data, and maintains inference efficiency by avoiding dense reconstruction. Our experimental setup and source code are available at https://github.com/kuiumdjiev/Per-Axis-Weight-Deltas-for-Frequent-Model-Updates.