Hybrid memory architecture for voltage scaling in ultra-low power multi-core biomedical processors

Technology scaling enables today the design of sensor-based ultra-low cost chips well suited for emerging applications such as wireless body sensor networks, urban life and environment monitoring. Energy consumption is the key limiting factor of this up-coming revolution and memories are often the energy bottleneck mainly due to leakage power. This paper proposes an ultra-low power multi-core architecture targeting eHealth monitoring systems, where applications involve collection of sequences of slow biomedical signals and highly parallel computations at very low voltage. We propose a hybrid memory architecture that combines 6T-SRAM and 8T-SRAM operating in the same voltage domain and capable of dispatching at high voltage a normal operation and at low voltage a fully reliable small memory partition (8T) while the rest of the memory (6T) is state-retentive. Our architecture offers significant energy savings with a low area overhead in typical eHealth Compressed Sensing-based applications.