Towards Artificial General Intelligence with Hybrid Tianjic Chip Architecture

Overview

Journal Nature

Specialty Science

Date 2019 Aug 2

PMID 31367028

Citations 96

Authors

Jing Pei

Lei Deng

Sen Song

Mingguo Zhao

Youhui Zhang

Shuang Wu

Guanrui Wang

Zhe Zou

Zhenzhi Wu

Wei He

Feng Chen

Ning Deng

Si Wu

Yu Wang

Yujie Wu

Zheyu Yang

Cheng Ma

Guoqi Li

Wentao Han

Huanglong Li

Huaqiang Wu

Rong Zhao

Yuan Xie

Luping Shi

Affiliations

Soon will be listed here.

Abstract

There are two general approaches to developing artificial general intelligence (AGI): computer-science-oriented and neuroscience-oriented. Because of the fundamental differences in their formulations and coding schemes, these two approaches rely on distinct and incompatible platforms, retarding the development of AGI. A general platform that could support the prevailing computer-science-based artificial neural networks as well as neuroscience-inspired models and algorithms is highly desirable. Here we present the Tianjic chip, which integrates the two approaches to provide a hybrid, synergistic platform. The Tianjic chip adopts a many-core architecture, reconfigurable building blocks and a streamlined dataflow with hybrid coding schemes, and can not only accommodate computer-science-based machine-learning algorithms, but also easily implement brain-inspired circuits and several coding schemes. Using just one chip, we demonstrate the simultaneous processing of versatile algorithms and models in an unmanned bicycle system, realizing real-time object detection, tracking, voice control, obstacle avoidance and balance control. Our study is expected to stimulate AGI development by paving the way to more generalized hardware platforms.

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