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Enabling Efficient Hardware Acceleration of Hybrid Vision Transformer (ViT) Networks at the Edge

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📝 Original Info

  • Title: Enabling Efficient Hardware Acceleration of Hybrid Vision Transformer (ViT) Networks at the Edge
  • ArXiv ID: 2507.14651
  • Date: 2025-07-19
  • Authors: Joren Dumoulin, Pouya Houshmand, Vikram Jain, Marian Verhelst

📝 Abstract

Hybrid vision transformers combine the elements of conventional neural networks (NN) and vision transformers (ViT) to enable lightweight and accurate detection. However, several challenges remain for their efficient deployment on resource-constrained edge devices. The hybrid models suffer from a widely diverse set of NN layer types and large intermediate data tensors, hampering efficient hardware acceleration. To enable their execution at the edge, this paper proposes innovations across the hardware-scheduling stack: a.) At the lowest level, a configurable PE array supports all hybrid ViT layer types; b.) temporal loop re-ordering within one layer, enabling hardware support for normalization and softmax layers, minimizing on-chip data transfers; c.) further scheduling optimization employs layer fusion across inverted bottleneck layers to drastically reduce off-chip memory transfers. The resulting accelerator is implemented in 28nm CMOS, achieving a peak energy efficiency of 1.39 TOPS/W at 25.6 GMACs/s.

💡 Deep Analysis

Deep Dive into Enabling Efficient Hardware Acceleration of Hybrid Vision Transformer (ViT) Networks at the Edge.

Hybrid vision transformers combine the elements of conventional neural networks (NN) and vision transformers (ViT) to enable lightweight and accurate detection. However, several challenges remain for their efficient deployment on resource-constrained edge devices. The hybrid models suffer from a widely diverse set of NN layer types and large intermediate data tensors, hampering efficient hardware acceleration. To enable their execution at the edge, this paper proposes innovations across the hardware-scheduling stack: a.) At the lowest level, a configurable PE array supports all hybrid ViT layer types; b.) temporal loop re-ordering within one layer, enabling hardware support for normalization and softmax layers, minimizing on-chip data transfers; c.) further scheduling optimization employs layer fusion across inverted bottleneck layers to drastically reduce off-chip memory transfers. The resulting accelerator is implemented in 28nm CMOS, achieving a peak energy efficiency of 1.39 TOPS/W

📄 Full Content

Hybrid vision transformers combine the elements of conventional neural networks (NN) and vision transformers (ViT) to enable lightweight and accurate detection. However, several challenges remain for their efficient deployment on resource-constrained edge devices. The hybrid models suffer from a widely diverse set of NN layer types and large intermediate data tensors, hampering efficient hardware acceleration. To enable their execution at the edge, this paper proposes innovations across the hardware-scheduling stack: a.) At the lowest level, a configurable PE array supports all hybrid ViT layer types; b.) temporal loop re-ordering within one layer, enabling hardware support for normalization and softmax layers, minimizing on-chip data transfers; c.) further scheduling optimization employs layer fusion across inverted bottleneck layers to drastically reduce off-chip memory transfers. The resulting accelerator is implemented in 28nm CMOS, achieving a peak energy efficiency of 1.39 TOPS/W at 25.6 GMACs/s.

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