The massive levels of integration following Moore\u27s Law making modern multi-core chips prevail in various domains ranging from scientific applications to bioinformatics applications for consumer electronics. With higher and higher number of cores on the same die traditional bus based interconnections are no longer a scalable communication infrastructure. On-chip networks were proposed enabled a scalable plug-and-play mechanism for interconnecting hundreds of cores on the same chip. Wired interconnects between the cores in a traditional Network-on-Chip (NoC) system, becomes a bottleneck with increase in the number of cores thereby increasing the latency and energy to transmit signals over them. Hence, there has been many alternative emerging interconnect technologies proposed, namely, 3D, photonic and multi-band RF interconnects. Although they provide better connectivity, higher speed and higher bandwidth compared to wired interconnects; they also face challenges with heat dissipation and manufacturing difficulties. On-chip wireless interconnects is one other alternative proposed which doesn\u27t need physical interconnection layout as data travels over the wireless medium. They are integrated into a hybrid NOC architecture consisting of both wired and wireless links, which provides higher bandwidth, lower latency, lesser area overhead and reduced energy dissipation in communication. An efficient media access control (MAC) scheme is required to enhance the utilization of the available bandwidth. A token-passing protocol proposed to grant access of the wireless channel to competing transmitters. This limits the number of simultaneous users of the communication channel to one although multiple wireless hubs are deployed over the chip. In principle, a Frequency Division Multiple Access (FDMA) based medium access scheme would improve the utilization of the wireless resources. However, this requires design of multiple very precise, high frequency transceivers in non-overlapping frequency channels. Therefore, the scalability of this approach is limited by the state-of-the-art in transceiver design. The Code Division Multiple Access (CDMA) enables multiple transmitter-receiver pairs to send data over the wireless channel simultaneously. The CDMA protocol can significantly increase the performance of the system while lowering the energy dissipation in data transfer. The CDMA based MAC protocol outperforms the wired counterparts and several other wireless architectures proposed in literature in terms of bandwidth and packet energy dissipation.
However, the reliability of CDMA based wireless NoC\u27s is limited, as the probability of error is eminent due to synchronization delays at the receiver. The thesis proposes the use of an advanced filter which improves the performance and also reduces the error due to synchronization delays. This thesis also proposes investigation of various channel modulation schemes on token passing wireless NoC\u27s to examine the performance and reliability of the system. The trade-off between performance and energy are established for the various conditions. The results are obtained using a modified cycle accurate simulator
