Improved on-chip router analytical power and area modeling

Over the course of this decade, uniprocessor chips have given way to multi-core chips which have become the primary building blocks of today´s computer systems. The presence of multiple cores on a chip shifts the focus from computation to communication as a key bottleneck to achieving performance improvements. As industry moves towards many-core chips, networks-on-chip (NoCs) are emerging as the scalable fabric for interconnecting the cores. With power now the first-order design constraint, early-stage estimation of NoC power has become crucially important. Existing power models (e.g., ORION 2.0 [12], Xpipes [7], etc.) are based on certain router microarchitecture and circuit implementation. Therefore, when validated against different NoC prototypes - different router implementations - we saw significant deviation (up to 40% on average) that can lead to erroneous NoC design choices. This has prompted our development of a new, accurate architecture- and circuit implementation-independent router power and area modeling methodology with complete portability across existing NoC component libraries. Also, validation against a range of implemented router designs confirms substantial improvement in accuracy over existing models.