电力线通信的混合电源/信号引脚SOC设计

2015 ACM/IEEE International Workshop on System Level Interconnect Prediction (SLIP) Pub Date : 2015-06-06 DOI:10.1109/SLIP.2015.7171711

Xiang Zhang, Yang Liu, R. Coutts, Chung-Kuan Cheng

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引用次数: 1

摘要

现代片上系统(soc)的球栅阵列(BGA)中可用引脚的数量已被讨论为处理器性能的主要瓶颈之一，例如支持多核的便携式设备，其中封装尺寸和PCB平面设计受到严格限制。典型的SOC封装分配一半以上的引脚用于供电，导致用于片外通信的IO引脚数量大大减少。我们观察到，对电源和接地(P/G)引脚数量的要求是由最高性能状态和最差设计角驱动的，而soc在大多数时间处于较低的性能状态，以延长电池寿命。在此观察下，我们建议重用一些电源引脚作为片外数据传输的动态电源/信号引脚，以增加SOC低性能状态下的片外带宽。我们提出的方法提供每个混合引脚对20Gbps的带宽，同时对原始电力输送网络(PDN)设计的影响最小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Power line communication for hybrid power/signal pin SOC design

The number of available pins in ball grid array (BGA) of modern system-on-chips (SOCs) has been discussed as one of the major bottlenecks to the performance of the processors, for example many-core enabled portable devices, where the package size and PCB floorplan are tightly constrained. A typical SOC package allocates more than half of the pins for power delivery, resulting in the number of IO pins for off-chip communications is greatly reduced. We observe that the requirement for the number of power and ground (P/G) pins is driven by the highest performance state and the worst design corners, while SOCs are in lower performance state for most of the time for longer battery life. Under this observation, we propose to reuse some of the power pins as dynamic power/signal pins for off-chip data transmissions to increase the off-chip bandwidth during SOC low performance state. Our proposed method provides 20Gbps bandwidth per hybrid pin pair, while providing minimum impact to the original power delivery network (PDN) design.

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来源期刊

2015 ACM/IEEE International Workshop on System Level Interconnect Prediction (SLIP)

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