Univ.-Prof. Dr.-Ing. habil. Okyay Altay
Chair of Structural Engineering - Professor
Office address
Prof. Altay has held the Chair of Structural Analysis at the University of Siegen since 2024. Before that, he served at RWTH Aachen University as Senior Lecturer at the Chair of Structural Analysis and Structural Dynamics and as Managing Director of the Center for Wind and Earthquake Engineering. He completed his habilitation at RWTH in 2021 with research on adaptive vibration reduction, material modeling, and real-time simulations, and earned his doctorate with distinction in 2013 for his work on tuned liquid column dampers.
Prior to his academic career, he worked at Bernard Ingenieure in Vienna as a project manager and later as deputy managing director of the subsidiary RED Bernard, focusing on bridge monitoring and vibration reduction. He studied civil engineering at RWTH Aachen University with a specialization in structural engineering, after completing his schooling at TED Ankara College in Turkey.
Publications
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Multiscale fluid–structure coupled real-time hybrid simulation of monopile wind turbines with vibration control devices
Multiscale fluid–structure coupled real-time hybrid simulation of monopile wind turbines with vibration control devices
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Multiscale fluid–structure coupled real-time hybrid simulation of monopile wind turbines with vibration control devices
Multiscale fluid–structure coupled real-time hybrid simulation of monopile wind turbines with vibration control devices
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Physics-informed deep operator network for predicting martensite evolution in superelastic shape memory alloys through cyclic tensile tests
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Solving large numerical substructures in real‐time hybrid simulations using proper orthogonal decomposition
Data generation framework for inverse modeling of nonlinear systems in structural dynamics applications
Data generation framework for inverse modeling of nonlinear systems in structural dynamics applications
Effects of variational formulations on physics‐informed neural network performance in solid mechanics
Effects of variational formulations on physics‐informed neural network performance in solid mechanics
Data generation framework for inverse modeling of nonlinear systems in structural dynamics applications
Data generation framework for inverse modeling of nonlinear systems in structural dynamics applications
Lateral vibration control of monopile supported offshore wind turbines with toroidal tuned liquid column dampers
Lateral vibration control of monopile supported offshore wind turbines with toroidal tuned liquid column dampers