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Switched-Beam 60 GHz Endfire Circular Patch Planar Array With Integrated 2-D Butler Matrix for Chip-to-Chip Space-Surface Wave Communications
The complexity of chip interconnection on a multicore multichip (MCMC) module using the traditional wired interconnects increases with the chip count. The global wired interconnects that run across the entire module must be made longer as more chips are placed on a larger module. Since the interconnect delay grows as the square of the interconnect length, the global wired interconnects can become a major bottleneck of the computing performance in such systems.
This dissertation presents a new type of hybrid space-surface wave interconnect (HSSW-I) using 60 GHz switched-beam antenna arrays to provide high-speed communication between the chips. The antennas communicate at near the speed of light through radiation in the air above the chips and through surface waves at the air-dielectric interface, and thus avoid lengthy delays. Each array consists of four center-fed circular patch elements with side vias in a 2 × 2 planar grid arrangement. The arrays enable multi-gigabits-per-second (Gbps) reconfigurable interchip communication when integrated with the proper chip transceivers. The main beam of the array is switched in the horizontal plane containing the chips, by changing the interelement phase shifts. The switching of the main beam is analyzed and verified through full-wave simulation. A compact two-dimensional (2-D) Butler matrix feed network is designed, implemented, and integrated with the circular patch planar array. The matrix is a four-input, four-output, i.e., 4 × 4 network consisting of four interconnected quadrature (90°) hybrid couplers and allows endfire scanning of the array main beam along the four diagonal directions in the horizontal plane. The realized antenna module is a thin multilayer microstrip (MS) structure with a footprint small enough to fit over a typical multicore chip. The antenna module provides a seamless and practical way to achieve reconfigurable interchip communication in MCMC systems. A multiantenna module (MAM) consisting of five antenna modules that emulates diagonal interchip communication in MCMC systems is fabricated. The simulation and measurement of the transmission coefficients between the antenna modules on the MAM are performed, and the signal-to-noise ratio (SNR) and signal-to-noise-plus-interference ratio (SNIR) of the links are calculated. A link decomposition simulation technique to determine the relative contribution of space and surface waves is also applied. A transmission link model is devised based on the leaky wave effect shown by the antenna arrays and the model coefficients are determined from the simulation data. The link model is then extrapolated at various distances and compared with more measurement and simulation results for verification. Finally, realistic link budget calculations are performed based on the measured and simulated data. The calculations show that the antenna modules using the HSSW-I can achieve raw data transfer rates up to 42.24 Gbps at 20 mm distance with low bit error rates (BERs) in the absence of interference, when used with the state-of-the-art 60 GHz complementary metal oxide semiconductor (CMOS) transceivers