Heterogeneous integration of high-density analog crossbar for advanced data processing

用于高级数据处理的高密度模拟交叉开关的异构集成

• 批准号: 506289-2017
• 负责人: Drouin, Dominique
• 金额: $ 13.84万
• 依托单位: Université de Sherbrooke
• 依托单位国家: 加拿大
• 项目类别: Strategic Projects - Group
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=642087
• 关键词: Heterogeneous; integration; density; analog; crossbar

Information and Communication Technology (ICT) is currently experiencing significant mutations that will modify our interactions with electronics. Computing systems are expected to emerge with viable solutions for large, heterogeneous and unstructured data processing. Since conventional systems are fundamentally not adapted to this class of problem, alternative solutions are envisioned and demand a complete shift in the computing paradigm, architecture and technology. To this end, the bio-inspired computing model appears as a promising solution to conventional computing since these systems can manage multi-sensory inputs with very large bandwidth in real time and with low energy consumption. Along these lines, artificial neural networks have experienced renewed interest in recent years, outperforming humans in visual recognition tasks and gaming. Nevertheless, such systems would benefit immensely from a dense, parallel and distributed memory (synapses) along the computing nodes (neurons). We propose in this project to build an efficient and versatile system for the future development of machine learning hardware, and more precisely, we propose a scalable, flexible and innovative strategy for the implementation of the synaptic weight and the associated Multiply and ACcumulate operation (MAC), one of the most demanding resource for efficient ML hardware. We will capitalize on an ideal balance between CMOS performance and specific features available with emerging memory devices (i.e. synapses). HIDATA proposes two levels of integration: (i) we will use an advanced system-in-package approach in order to optimize heterogeneous integration of memory devices on CMOS chips. Here, we will design and fabricate memory chips interconnected via flip-chip technology on an active interposer which will ensure dynamic signal management and routing while minimizing memory device variability and preserving CMOS design flexibility. (ii) We will implement a massively parallel and dense memory array via multiple passive crossbar interconnection in a system-on-chip strategy. Active amplification between passive crossbars will enable ultra-high memory density while preserving optimal control of the memory devices.

信息和通信技术（ICT）目前正在经历重大的突变，这将改变我们与电子产品的互动。计算系统有望为大型、异构和非结构化数据处理提供可行的解决方案。由于传统系统从根本上不适合这类问题，因此设想了替代解决方案，并要求在计算范式、体系结构和技术方面进行彻底转变。为此，生物启发的计算模型似乎是传统计算的一个有前途的解决方案，因为这些系统可以实时管理多感官输入，带宽非常大，能耗很低。近年来，人工神经网络在视觉识别任务和游戏方面的表现超越了人类，从而重新引起了人们的兴趣。然而，这样的系统将从沿计算节点（神经元）的密集、并行和分布式内存（突触）中获益良多。在这个项目中，我们提出为未来机器学习硬件的发展建立一个高效、通用的系统，更准确地说，我们提出了一个可扩展、灵活和创新的策略来实现突触权重和相关的乘法和累积操作（MAC），这是高效机器学习硬件最需要的资源之一。我们将利用CMOS性能和新兴存储器件（即突触）的特定功能之间的理想平衡。HIDATA提出了两个级别的集成：(i)我们将使用先进的系统级封装方法，以优化CMOS芯片上存储器件的异构集成。在这里，我们将设计和制造通过倒装芯片技术在有源中间层上互连的存储芯片，这将确保动态信号管理和路由，同时最大限度地减少存储器件的可变性并保持CMOS设计的灵活性。（ii）我们将在片上系统策略中通过多个无源交叉棒互连实现大规模并行和密集存储阵列。无源交叉杆之间的有源放大将实现超高的存储密度，同时保持对存储器件的最佳控制。