TY - JOUR T1 - AdaptivFloat: A Floating-Point Based Data Type for Resilient Deep Learning Inference JF - arXiv preprint arXiv:1909.13271 Y1 - 2019 A1 - Tambe, Thierry A1 - Yang,Yu A1 - Wan, Zishen A1 - Deng, Yuntian A1 - Vijay Reddi A1 - Rush, Alexander A1 - David Brooks A1 - Gu Wei AB - Conventional hardware-friendly quantization methods, such as fixed-point or integer, tend to perform poorly at very low word sizes as their shrinking dynamic ranges cannot adequately capture the wide data distributions commonly seen in sequence transduction models. We present AdaptivFloat, a floating-point inspired number representation format for deep learning that dynamically maximizes and optimally clips its available dynamic range, at a layer granularity, in order to create faithful encoding of neural network parameters. AdaptivFloat consistently produces higher inference accuracies compared to block floating-point, uniform, IEEE-like float or posit encodings at very low precision (≤ 8-bit) across a diverse set of state-of-the-art neural network topologies. And notably, AdaptivFloat is seen surpassing baseline FP32 performance by up to +0.3 in BLEU score and -0.75 in word error rate at weight bit widths that are ≤ 8-bit. Experimental results on a deep neural network (DNN) hardware accelerator, exploiting AdaptivFloat logic in its computational datapath, demonstrate per-operation energy and area that is 0.9× and 1.14×, respectively, that of equivalent bit width integer-based accelerator variants. UR - https://doi.org/10.48550/arXiv.1909.13271 ER -