English

ESPACE: Dimensionality Reduction of Activations for Model Compression

Machine Learning 2024-10-10 v1

Abstract

We propose ESPACE, an LLM compression technique based on dimensionality reduction of activations. Unlike prior works on weight-centric tensor decomposition, ESPACE projects activations onto a pre-calibrated set of principal components. The activation-centrality of the approach enables retraining LLMs with no loss of expressivity; while at inference, weight decomposition is obtained as a byproduct of matrix multiplication associativity. Theoretical results on the construction of projection matrices with optimal computational accuracy are provided. Experimentally, we find ESPACE enables 50% compression of GPT3, Llama2, and Nemotron4 models with small accuracy degradation, as low as a 0.18 perplexity increase on GPT3-22B. At lower compression rates of 20% to 40%, ESPACE drives GPT3 models to outperforming their baseline, by up to a 0.38 decrease in perplexity for GPT3-8B. ESPACE also reduces GEMM execution time and prefill inference latency on existing hardware. Comparison with related works on compressing Llama2-7B via matrix factorization shows that ESPACE is a first step in advancing the state-of-the-art in tensor decomposition compression of LLMs.

Cite

@article{arxiv.2410.05437,
  title  = {ESPACE: Dimensionality Reduction of Activations for Model Compression},
  author = {Charbel Sakr and Brucek Khailany},
  journal= {arXiv preprint arXiv:2410.05437},
  year   = {2024}
}

Comments

Published as a paper at NeurIPS 2024

R2 v1 2026-06-28T19:12:02.866Z