[摘要] As CMOS technology improves, the trend of processor designs has gone towards multi-core architectures. Networks-on-Chips (NoCs) have become popular on-chip interconnect fabrics that connect the ever-increasing cores because of their ability to provide high-bandwidth. However, as the number of cores keeps increasing, the endto- end packet latency and the total network power begin to pose tight constraints on NoC designs. In this thesis, we studied architecture proposals designed to tackle this latency and power budget issue. We also studied the impact of applying advanced circuit techniques to these architecture proposals and how to implement these techniques while realizing a NoC design. The thesis begins with an evaluation of physical express topologies and the virtual express topologies that enable the bypassing of intermediate router pipelines. The bypassing of pipeline stages help reduce both end-to-end latency and power consumption since fewer resources are used. We observed that both topologies have similar low-traffic-load latencies and that virtual express topologies result in higher throughput and are more robust across traffic patterns. Physical express topologies, however, deliver a better throughput/watt and can leverage the low-swing link circuits to lower the latency and increase the throughput. Next, then we identified that crossbars, in addition to links, can obtain benefit from the low-swing circuit techniques. We thus developed a layout generation tool for low-swing crossbars and links due to the inability of the existing tools for physical designs to generate these low-swing circuits automatically. The generated crossbars and links using our tool showed 50% energy saving compared to the full-swing synthesized counterpart. We also demonstrated a case study with a router synthesized with the generated crossbar and links.