Multi-device inference can reduce Transformer latency by parallelizing computation. However, existing methods require high inter-device bandwidth, making them impractical for bandwidth-constrained environments. We present ASTRA, a communication-efficient framework that integrates sequence parallelism with mixed-precision attention, where non-local token embeddings are transmitted as low-bit vector-quantized codes while local attention remains full precision. To preserve accuracy under aggressive compression, ASTRA introduces Noise-Augmented Quantization and Distributed Class Tokens. Across vision and language models (e.g., ViT and GPT2), ASTRA achieves up to 2.64× speedup over single-device inference and up to 15.25× over prior multi-device baselines while operating at bandwidths as low as 10 Mbps. ASTRA remains robust on large models (e.g., Llama-3-8B) even under non-ideal network conditions such as packet loss and dynamic networks.
@article{arxiv.2505.19342,
title = {ASTRA: Communication-Efficient Acceleration for Multi-Device Transformer Inference},
author = {Xiao Liu and Lijun Zhang and Deepak Ganesan and Hui Guan},
journal= {arXiv preprint arXiv:2505.19342},
year = {2026}
}