10.7 A 105GOPS 36mm2 heterogeneous SDR MPSoC with energy-aware dynamic scheduling and iterative detection-decoding for 4G in 65nm CMOS

Modern mobile communication systems face conflicting design constraints. On the one hand, the expanding variety of transmission modes calls for highly flexible solutions supporting the ever-growing number and diversity of application requirements. On the other hand, stringent power restrictions (e.g., at femto base stations and terminals) must be considered, while satisfying the demanding performance requirements. In order to cope with these issues, existing SDR platforms, e.g. [1-2], propose an MPSoC with a heterogeneous array of processing elements (PEs). MPSoC solutions provide programmability and parallelism yielding flexibility, processing performance and power efficiency. To schedule the resources and to apply power gating, a static approach is employed. In contrast, we present a heterogeneous MPSoC platform (Tomahawk2) with runtime scheduling and fine-grained hierarchical power management. This solution can fully adapt to the dynamically varying workload and semi-deterministic behavior in modern concurrent wireless applications. The proposed dynamic scheduler (CoreManager, CM) can be implemented either in software on a general-purpose processor or on a dedicated application-specific hardware unit. It is evident that the software approach offers the highest degree of flexibility; however, it may become a performance-bottleneck for complex applications. A high-throughput ASIC was presented in [3], but this solution does not permit scheduling algorithms to be adjusted. In this work, these limitations are overcome by implementing the CM on an ASIP.