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Paper detail

Ghosted Layers: Unconstrained Activation Alignment for Recovering Layer-Pruned LLMs

Layer pruning removes entire Transformer decoder blocks from large language models, but introduces a mismatch between the hidden state received by the next surviving layer and the distribution it was trained to process, leading to significant performance degradation. We propose Ghosted Layers, a training-free recovery module that addresses this issue by solving a boundary activation alignment problem. Our method derives a closed-form optimal linear operator from a small calibration set to reconstruct the activation discrepancy introduced by the pruned layers. We show that this solution corresponds to the unconstrained optimum of the alignment objective, whereas existing methods are restricted to constrained solutions over limited operator subspaces. Experiments across multiple LLM backbones and pruning strategies demonstrate that our method consistently improves accuracy and perplexity over prior training-free baselines, while preserving the efficiency gains of layer pruning.

preprint2026arXivOpen access
Vincent-Daniel YunJunhyuk JoSai Praneeth KarimireddySunwoo Lee
PerformanceMachine LearningArtificial Intelligence
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Vincent-Daniel YunJunhyuk JoSai Praneeth KarimireddySunwoo Lee

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