The transition to 64-bit computing in other domains (e.g., genomics, climate modeling) has enabled simulations with higher fidelity. However, a dedicated 64-bit wind modeling framework has been lacking. This paper proposes , a purpose-built software stack that exploits 64-bit address space and instruction sets (e.g., AVX-512) to overcome prior constraints.
Wind64, wind energy, high-performance computing, large-eddy simulation, 64-bit computing, wind farm optimization. 1. Introduction Wind energy accounts for over 8% of global electricity generation (IEA, 2025). Accurate modeling of wind flow across complex terrains and large turbine arrays remains challenging due to the multiscale nature of atmospheric turbulence. Traditional models often run on 32-bit architectures or legacy codebases, limiting domain size and real-time applicability.
[4] HDF Group. (2024). HDF5 64-bit features and performance. HDF5 Documentation.
The transition to 64-bit computing in other domains (e.g., genomics, climate modeling) has enabled simulations with higher fidelity. However, a dedicated 64-bit wind modeling framework has been lacking. This paper proposes , a purpose-built software stack that exploits 64-bit address space and instruction sets (e.g., AVX-512) to overcome prior constraints.
Wind64, wind energy, high-performance computing, large-eddy simulation, 64-bit computing, wind farm optimization. 1. Introduction Wind energy accounts for over 8% of global electricity generation (IEA, 2025). Accurate modeling of wind flow across complex terrains and large turbine arrays remains challenging due to the multiscale nature of atmospheric turbulence. Traditional models often run on 32-bit architectures or legacy codebases, limiting domain size and real-time applicability.
[4] HDF Group. (2024). HDF5 64-bit features and performance. HDF5 Documentation.
