The scientist’s investigation covers issues in Control theory, Galerkin method, Wake, Control engineering and Vortex shedding. Gilead Tadmor has researched Control theory in several fields, including Simple and Riccati equation. His Galerkin method study combines topics from a wide range of disciplines, such as Cylinder, Incompressible flow, Mathematical analysis and Mean flow.
His studies deal with areas such as Artificial neural network, Reduced order and Nonlinear system as well as Wake. His Control engineering research is multidisciplinary, incorporating perspectives in Ripple and Turbulence. His Vortex shedding study combines topics in areas such as Flow control and Classical mechanics.
His primary areas of investigation include Control theory, Galerkin method, Mechanics, Linear system and Applied mathematics. His work deals with themes such as Control engineering and Riccati equation, which intersect with Control theory. Gilead Tadmor has included themes like Flow, Wake, Mathematical analysis and Classical mechanics in his Galerkin method study.
Gilead Tadmor interconnects Cylinder, Computational fluid dynamics and Vortex shedding in the investigation of issues within Wake. His study in Vortex shedding is interdisciplinary in nature, drawing from both Flow control and Kármán vortex street. The Vortex, Drag, Reynolds number and Turbulence research he does as part of his general Mechanics study is frequently linked to other disciplines of science, such as Shear, therefore creating a link between diverse domains of science.
Gilead Tadmor mainly focuses on Galerkin method, Wake, Control theory, Nonlinear system and Applied mathematics. His Galerkin method research incorporates elements of Flow and Mathematical analysis, Interpolation. His Wake study incorporates themes from Cylinder, Turbulence and Classical mechanics.
Gilead Tadmor combines subjects such as Feature extraction and Mechanics, Vorticity, Vortex with his study of Cylinder. The study incorporates disciplines such as Sampling and Model predictive control in addition to Control theory. As a part of the same scientific family, Gilead Tadmor mostly works in the field of Applied mathematics, focusing on Krylov subspace and, on occasion, Computational fluid dynamics.
Gilead Tadmor mostly deals with Nonlinear system, Wake, Galerkin method, Turbulence and Focus. His Nonlinear system study necessitates a more in-depth grasp of Control theory. His Control theory research incorporates themes from Time complexity and Partial differential equation.
The various areas that Gilead Tadmor examines in his Wake study include Cylinder, Lyapunov exponent, Vorticity and Vortex shedding. His Galerkin method research is multidisciplinary, incorporating elements of Mathematical analysis and Classical mechanics. The concepts of his Turbulence study are interwoven with issues in Artificial neural network, Corollary, Control engineering and Reduced order.
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A hierarchy of low-dimensional models for the transient and post-transient cylinder wake
Bernd R. Noack;Konstantin Afanasiev;Marek Morzynski;Gilead Tadmor.
Journal of Fluid Mechanics (2003)
Feedback shear layer control for bluff body drag reduction
Mark Pastoor;Lars Henning;Bernd R. Noack;Rudibert King.
Journal of Fluid Mechanics (2008)
Reduced-Order Modelling for Flow Control
Bernd R. Noack;Marek Morzynski;Gilead Tadmor.
Worst-case design in the time domain: The maximum principle and the standard H ∞ problem.
Mathematics of Control, Signals, and Systems (1990)
Design and implementation of an adaptive controller for torque ripple minimization in PM synchronous motors
V. Petrovic;R. Ortega;A.M. Stankovic;G. Tadmor.
IEEE Transactions on Power Electronics (2000)
H ∞ optimal sampled-data control in continuous time systems
International Journal of Control (1992)
Model-based Control of Vortex Shedding Using Low-dimensional Galerkin Models
Johannes Gerhard;Mark Pastoor;Rudibert King;Bernd Noack.
33rd AIAA Fluid Dynamics Conference and Exhibit (2003)
The standard H/sub /spl infin// problem in systems with a single input delay
IEEE Transactions on Automatic Control (2000)
A Finite-Time Thermodynamics of Unsteady Fluid Flows
Bernd R. Noack;Michael Schlegel;Boye Ahlborn;Gerd Mutschke.
Journal of Non-Equilibrium Thermodynamics (2008)
On robust control analysis and design for load frequency regulation
A.M. Stankovic;G. Tadmor;T.A. Sakharuk.
IEEE Transactions on Power Systems (1998)
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