Negar Neda, Salim Ullah, A. Ghanbari, H. Mahdiani, M. Modarressi, Akash Kumar
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Multi-Precision Deep Neural Network Acceleration on FPGAs
Quantization is a promising approach to reduce the computational load of neural networks. The minimum bit-width that preserves the original accuracy varies significantly across different neural networks and even across different layers of a single neural network. Most existing designs over-provision neural network accelerators with sufficient bit-width to preserve the required accuracy across a wide range of neural networks. In this paper, we present mpDNN, a multi-precision multiplier with dynamically adjustable bit-width for deep neural network acceleration. The design supports run-time splitting an arithmetic operator into multiple independent operators with smaller bit-width, effectively increasing throughput when lower precision is required. The proposed architecture is designed for FPGAs, in that the multipliers and bit-width adjustment mechanism are optimized for the LUT-based structure of FPGAs. Experimental results show that by enabling run-time precision adjustment, mpDNN can offer 3-15x improvement in throughput.
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