Exploring Wireless Technology For Off-Chip Memory Access

The trend of shifting from multi-core to many-core processors is exceeding the data-carrying capacity of the traditional on-chip communication fabric. While the importance of the on-chip communication paradigm cannot be denied, the off-chip memory access latency is fast becoming an important challenge. As more memory intensive applications are developed, off-chip memory access will limit the performance of chip multi-core processors (CMPs). However, with the shrinkage of transistor dimension, the energy consumption and the latency of the traditional metallic interconnects are increasing due to smaller wire widths, longer wire lengths, and complex multi-hop routing requirements. In contrast, emerging wireless technology requires lower energy with single-hop communication, albeit with limited bandwidth (at a 60 GHz center frequency). In this paper, we have proposed several hybrid-wireless architectures to access off-chip memory by exploiting frequency division multiplexing (FDM), time division multiplexing (TDM), and space division multiplexing (SDM) techniques. We explore the design-space of building hybrid-wireless interconnects by considering conservative and aggressive wireless bandwidths and directionality. Our hybrid-wireless architectures require a maximum of two hops and show 10.91% reduction in execution time compared to a baseline metallic architecture. In addition, the proposed hybrid-wireless architectures show on an average 62.07% and 32.52% energy per byte improvement over traditional metallic interconnects for conservative and aggressive off-chip metallic link energy-efficiency respectively. Nevertheless, the proposed hybrid-wireless architectures incur an area overhead due to the higher transceiver area requirement.