Abstract
High-performance long-range NoC link enables efficient implementation of network-on-chip topologies which inherently require high-performance long-distance point-to-point communication such as torus and fat-tree structures. In addition, the performance of other topologies, such as mesh, can be improved by using high-performance link between few selected remote nodes. We presented novel implementation of high-performance long-range NoC link based on multilevel current-mode signaling and delay-insensitive two-phase 1-of-4 encoding. Current-mode signaling reduces the communication latency of long wires significantly compared to voltage-mode signaling, making it possible to achieve high throughput without pipelining and/or using repeaters. The performance of the proposed multilevel current-mode interconnect is analyzed and compared with two reference voltage mode interconnects. These two reference interconnects are designed using two-phase 1-of-4 encoded voltage-mode signaling, one with pipeline stages and the other using optimal repeater insertion. The proposed multilevel current-mode interconnect achieves higher throughput and lower latency than the two reference interconnects. Its throughput at 8 mm wire length is 1.222 GWord/s which is 1.58 and 1.89 times higher than the pipelined and optimal repeater insertion interconnects, respectively. Furthermore, its power consumption is less than the optimal repeater insertion voltage-mode interconnect, at 10 mm wire length its power consumption is 0.75 mW while the reference repeater insertion interconnect is 1.066 mW. The effect of crosstalk is analyzed using four-bit parallel data transfer with the best-case and worst-case switching patterns and a transmission line model which has both capacitive coupling and inductive coupling.
Highlights
Network-on-Chip (NoC) is the most viable solution for onchip communication that provides good scalability and enables gigascale integration in single-chip systems
We presented a high-performance delay-variation-insensitive long on-chip interconnect which uses two-phase 1-of-4 encoding and multilevel current-mode signaling. This interconnect is a promising candidate for long-range NoC communication links since it has low latency, high throughput, and low power-throughput ratio
The performance analysis shows that the current-mode interconnect has higher throughput and lower latency than the two reference interconnects
Summary
Network-on-Chip (NoC) is the most viable solution for onchip communication that provides good scalability and enables gigascale integration in single-chip systems. The impact of process, supply voltage, and temperature variations on the performance and reliability of long on-chip links is expected to increase as technology scales down [5] These variations cause the signal propagation delay through interconnects to be uncertain which in turn affects the performance and reliability of the system significantly. It is immune to power supply noise and has reduced sensitivity to process-induced variations Due to these advantages, we use current-mode signaling for the implementation of high-performance long-range NoC links. In this work we combine self-timed 1-of-4 encoded communication protocol with current-mode signaling for achieving a high-performance delay-variation-insensitive long-range on-chip communication.
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