Several interesting topologies emerge by incorporating the third dimension in networks-on-chip (NoC). The speed and power consumption of 3-D NoC are compared to that of 2-D NoC. Physical constraints, such as the maximum number of planes that can be vertically stacked and the asymmetry between the horizontal and vertical communication channels of the network, are included in speed and power consumption models of these novel 3-D structures. An analytic model for the zero-load latency of each network that considers the effects of the topology on the performance of a 3-D NoC is developed. Tradeoffs between the number of nodes utilized in the third dimension, which reduces the average number of hops traversed by a packet, and the number of physical planes used to integrate the functional blocks of the network, which decreases the length of the communication channel, is evaluated for both the latency and power consumption of a network. A performance improvement of 40% and 36% and a decrease of 62% and 58% in power consumption is demonstrated for 3-D NoC as compared to a traditional 2-D NoC topology for a network size of = 128 and = 256 nodes, respectively.
Three-dimensional (3-D) integration is an important technology that addresses fundamental limitations of on-chip interconnects. Several design issues related to 3-D circuits, such as multi-plane synchronization, however, need to be addressed. A comparison of three 3-D clock distribution network topologies is presented in this paper. Experimental results of a 3-D test circuit manufactured by the MIT Lincoln Laboratories are also described. Successful operation of the 3-D test circuit at 1.4 GHz is demonstrated. Clock skew and power dissipation measurements for the different clock topologies are also provided.
A heterogeneous interconnect architecture can be a useful approach for the design of 3-D FPGAs. A methodology to investigate heterogeneous interconnection schemes for 3-D FPGAs under different 3-D fabrication technologies is proposed. Application of the proposed methodology on benchmark circuits demonstrates an improvement in delay, power consumption, and total wire-length of approximately 41%, 32%, and 36%, respectively, as compared to 2-D FPGAs. These improvements are additional to reducing the number of interlayer connections. The fewer interlayer connections are traded off for a higher yield. An area model to evaluate this trade-off is presented. Results indicate that a heterogeneous 3-D FPGA requires 37% less area as compared to a homogeneous 3-D FPGA. Consequently, the heterogeneous FPGAs can exhibit a higher manufacturing yield. A design toolset is also developed to support the design and exploration of various performance metrics for the proposed 3-D FPGAs.
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