Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Program
-
Field
-
with provable performance for nonlinear systems. About us The Department of Mathematical Science provides a creative, dynamic and innovative environment where research, education, and societal
-
to the lack of generation inertia worsening power system stability. Control of such a complex system relies on detailed understanding and real-time modelling of the nonlinear dynamics resulting from
-
monitoring techniques. Study the interaction patterns of control and protection. Solve large systems of linear and nonlinear equations using applied mathematics and numerical methods. Where to apply Website
-
optimization, including integer, nonlinear, and combinatorial optimization; global and non-convex optimization; machine learning for optimization; explainable artificial intelligence; heuristic and metaheuristic
-
solutions across the natural sciences. Your workplace You will be employed at the Department of Mathematics in the Division of Applied Mathematics, https://liu.se/en/organisation/liu/mai/tima . The research
-
, and laboratory operations. Responsibilities include: Applying advanced understanding of ultrafast spectroscopy, nonlinear optics, and materials physics to research problems. Conducting literature
-
? Please make sure that your ORCID-profile (https://orcid.org ) works: your publications are listed and public (Set visibility: Everyone). You cannot apply to this job without an ORCID profile
-
University of North Carolina at Chapel Hill | Chapel Hill, North Carolina | United States | 1 day ago
the Principal Investigator on research in Lagrangian geometry and fully nonlinear partial differential equations, including the construction of minimal Lagrangians in complex hyperbolic space and their
-
approaches, where nonlinear FEM, rule-based design, parametric design etc and general model-based systems engineering approaches are a plus. Experience applying artificial intelligence and machine learning
-
Innovative electrical interfaces for solid-state electrocaloric cooling using ferroelectric ceramics
that are possibly nonlinear. 2. Based on the global approach performed in the previous point, design and implementation of efficient electrical interfaces featuring charge recovery to ensure regenerative cycles