Grid optimization, renewable forecasting, and resource management
AI that balances power grids in real-time. These systems forecast demand, optimize renewable dispatch, manage battery storage, and schedule maintenance—learning continuously from weather, market, and operational data. The result: higher reliability, lower costs, and more renewables on the grid without overbuilding infrastructure.
This application area focuses on using data‑driven models to understand, search, and design proteins across sequence, structure, and function. Instead of treating protein structure prediction, binding analysis, and sequence generation as separate tasks, these systems integrate them into unified workflows that support target identification, candidate design, and optimization. They move beyond single static structures to capture realistic conformational ensembles and the ‘dark’ or disordered regions that are hard to probe experimentally. It matters because protein‑based drugs, enzymes, and biologics underpin a large and growing share of the pharmaceutical and industrial biotech markets, yet conventional discovery is slow, costly, and constrained by limited experimental data. By learning from sequences, 3D structures, energy landscapes, and textual annotations, these applications accelerate hit finding, improve mechanistic insight, and expand the space of tractable targets. Organizations use them to shorten R&D cycles, raise success rates in drug and biologic development, and open new therapeutic and industrial opportunities that were previously inaccessible.