An Ultra-Low Power NVM-Based Multi-Core Architecture for Embedded Bio Signal Processing

Healthcare delivery is evolving towards new Wireless Body Sensor Nodes (WBSN), which are miniaturized devices able to acquire, process and transmit subjects’ bio-signals in real time within a tiny energy budget. Recent efforts on AD converters and transmission schemes have enabled a major power consumption reduction of these components, thus leaving the embedded processing stage as the dominant power-hungry component. In this context, new multi-core architectures designed with smaller CMOS devices and aggressive voltage scaling greatly improve the energy efficiency of WBSNs, but originate reliability operation concerns. In this work we present a novel WBSN architecture equipped with a completely redesigned memory subsystem (including a low-voltage low-latency non-volatile partition), which operates in combination with an advanced code synchronization management to reduce the platform ower consumption by up to 82%.

An Ultra-Low Power NVM-Based Multi-Core Architecture for Embedded Bio Signal Processing

Accelerator-driven Data Arrangement to Minimize Transformers Run-time on Multi-core Architectures

Imaging sensor device using an array of single-photon avalanche diode photodetectors

Reinforcement Learning-Based Joint Reliability and Performance Optimization for Hybrid-Cache Computing Servers

Accelerator-driven Data Arrangement to Minimize Transformers Run-time on Multi-core Architectures

Imaging sensor device using an array of single-photon avalanche diode photodetectors

Reinforcement Learning-Based Joint Reliability and Performance Optimization for Hybrid-Cache Computing Servers