计算机科学
炸薯条
计算机硬件
高效能源利用
人工神经网络
巨量平行
嵌入式系统
人工智能
电气工程
并行计算
电信
工程类
作者
Stefano Ambrogio,Pritish Narayanan,Atsuya Okazaki,Andrea Fasoli,Charles Mackin,Kohji Hosokawa,Akiyo Nomura,Takeo Yasuda,A. Chen,Alexander Friz,Masatoshi Ishii,Jose Luquin,Yasuteru Kohda,Nicole Saulnier,Kevin Brew,S. Choi,Kang Min Ok,Timothy M. Philip,V. Chan,C. Silvestre
出处
期刊:Nature
[Nature Portfolio]
日期:2023-08-23
卷期号:620 (7975): 768-775
被引量:84
标识
DOI:10.1038/s41586-023-06337-5
摘要
Models of artificial intelligence (AI) that have billions of parameters can achieve high accuracy across a range of tasks1,2, but they exacerbate the poor energy efficiency of conventional general-purpose processors, such as graphics processing units or central processing units. Analog in-memory computing (analog-AI)3-7 can provide better energy efficiency by performing matrix-vector multiplications in parallel on 'memory tiles'. However, analog-AI has yet to demonstrate software-equivalent (SWeq) accuracy on models that require many such tiles and efficient communication of neural-network activations between the tiles. Here we present an analog-AI chip that combines 35 million phase-change memory devices across 34 tiles, massively parallel inter-tile communication and analog, low-power peripheral circuitry that can achieve up to 12.4 tera-operations per second per watt (TOPS/W) chip-sustained performance. We demonstrate fully end-to-end SWeq accuracy for a small keyword-spotting network and near-SWeq accuracy on the much larger MLPerf8 recurrent neural-network transducer (RNNT), with more than 45 million weights mapped onto more than 140 million phase-change memory devices across five chips.
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