The expected halt of traditional technology scaling is motivating increased heterogeneity in
high-performance computing (HPC) systems with the emergence of numerous specialized …

Across embedded, mobile, enterprise, and high performance computing systems, computer
architectures are becoming more heterogeneous and complex. This complexity is causing a …

In this work, we present a C ompiler-integrated, E xtensible D omain Specific System on
Chip R untime (CEDR) ecosystem to facilitate research toward addressing the challenges of …

From edge to exascale, computer architectures are becoming more heterogeneous and
complex. The systems typically have fat nodes, with multicore CPUs and multiple hardware …

The diversity of workload requirements and increasing hardware heterogeneity in emerging
high performance computing (HPC) systems motivate resource disaggregation. Resource …

RISC-V based architectures have gained attention for deployment on platforms from SoC to
HPC scale to meet the demands of a wide range of computational workloads that may …

Hybrid nanosystems, in which different components synergistically contribute to peculiar
properties, are an important example of how multidisciplinarity is now essential for …

Despite the pandemic, the last five years have been marked by an extraordinary
development of new advanced technologies, based not only on new materials but also on …

The future of high-performance computing (HPC) will be driven by the convergence of
physical simulation, artificial intelligence, machine learning, and data science computing …

Heterogeneous computing promise boost performance of scientific applications by allowing
massively parallel execution of computational tasks. However, manually managing …