Communication synthesis of networks-on-chip (NoC)

The emergence of networks-on-chip (NoC) as the communication infrastructure solution for complex multi-core SoCs presents communication synthesis challenges. This dissertation addresses the design and run-time management aspects of communication synthesis. Design reuse and the infeasibility of Intellectual Property (IP) core interface redesign, requires the development of a Core-Network Interface (CNI) which allows them to communicate over the on-chip network. The absence of intelligence amongst the NoC components, entails the introduction of a CNI capable of not only providing basic packetization and depacketization, but also other essential services such as reliability, power management, reconguration and test support. A generic CNI architecture providing these services for NoCs is proposed and evaluated in this dissertation. Rising on-chip communication power costs and reliability concerns due to these, motivate the development of a peak power management technique that is both scalable to dierent NoCs and adaptable to varying trac congurations. A scalable and adaptable peak power management technique - SAPP - is proposed and demonstrated. Latency and throughput improvements observed with SAPP demonstrate its superiority over existing techniques. Increasing design complexity make prediction of design lifetimes dicult. Post SoC deployment, an on-line health monitoring scheme, is essential to maintain con- dence in the correct operation of on-chip cores. The rising design complexity and IP core test costs makes non-concurrent testing of the IP cores infeasible. An on-line scheme capable of managing IP core test in the presence of executing applications is essential. Such a scheme ensures application performance and system power budgets are eciently managed. This dissertation proposes Concurrent On-Line Test (COLT) for NoC-based systems and demonstrates how a robust implementation of COLT using a Test Infrastructure-IP (TI-IP) can be used to maintain condence in the correct operation of the SoC

Power-aware NoC Reuse on the Testing of Core-based Systems

This work discusses the impact of power consumption on the test time of core-based systems, when an available on-chip network is reused as test access mechanism. A previously proposed technique for the reuse of an on-chip network is extended to consider power consumption during test, while minimizing the system testing time. Experimental results with the ITC'02 SoC benchmarks show that although power constraints can preclude the full exploration of the network parallelism, this platform is still a powerful mechanism for the system test time reduction at a very low cost