This paper proposes a novel approach for learning a data-driven quadratic manifold from high-dimensional data, then employing this quadratic manifold to derive efficient physics-based reduced-order models. The key ingredient of the approach is a polynomial mapping between high-dimensional states and a low-dimensional embedding. This mapping consists of two parts: a representation in a linear subspace (computed in this work using the proper orthogonal decomposition) and a quadratic component. The approach can be viewed as a form of data-driven closure modeling, since the quadratic component introduces directions into the approximation that lie in the orthogonal complement of the linear subspace, but without introducing any additional degrees...
We propose a nonlinear reduced basis method for the efficient approximation of parametrized partial ...
This work explores the physics-driven machine learning technique Operator Inference (OpInf) for pred...
In this work we introduce a manifold learning-based method for uncertainty quantification (UQ) in sy...
Linear projection schemes like Proper Orthogonal Decomposition can efficiently reduce the dimensions...
This work formulates a new approach to reduced modeling of parameterized, time-dependent partial dif...
This work presents two novel approaches for the symplectic model reduction of high-dimensional Hamil...
A quadratic approximation manifold is presented for performing nonlinear, projection-based, model or...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
Large scale dynamical systems (e.g. many nonlinear coupled differential equations)can often be summa...
Model reduction in computational mechanics is generally addressed with linear dimensionality reducti...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
This work presents a nonintrusive projection-based model reduction approach for full models based on...
Real-time applications of control require the ability to accurately and efficiently model the observ...
This is the peer reviewed version of the following article: Diez, P. [et al.]. Nonlinear dimensional...
In this paper we develop reduced-order models (ROMs) for dynamic, parameter-dependent, linear and n...
We propose a nonlinear reduced basis method for the efficient approximation of parametrized partial ...
This work explores the physics-driven machine learning technique Operator Inference (OpInf) for pred...
In this work we introduce a manifold learning-based method for uncertainty quantification (UQ) in sy...
Linear projection schemes like Proper Orthogonal Decomposition can efficiently reduce the dimensions...
This work formulates a new approach to reduced modeling of parameterized, time-dependent partial dif...
This work presents two novel approaches for the symplectic model reduction of high-dimensional Hamil...
A quadratic approximation manifold is presented for performing nonlinear, projection-based, model or...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
Large scale dynamical systems (e.g. many nonlinear coupled differential equations)can often be summa...
Model reduction in computational mechanics is generally addressed with linear dimensionality reducti...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
This work presents a nonintrusive projection-based model reduction approach for full models based on...
Real-time applications of control require the ability to accurately and efficiently model the observ...
This is the peer reviewed version of the following article: Diez, P. [et al.]. Nonlinear dimensional...
In this paper we develop reduced-order models (ROMs) for dynamic, parameter-dependent, linear and n...
We propose a nonlinear reduced basis method for the efficient approximation of parametrized partial ...
This work explores the physics-driven machine learning technique Operator Inference (OpInf) for pred...
In this work we introduce a manifold learning-based method for uncertainty quantification (UQ) in sy...