This paper presents an efficient two-stage project-and-balance scheme for passivity-preserving model order reduction. Orthogonal dominant eigenspace projection is implemented by integrating the Smith method and Krylov subspace iteration. It is followed by stochastic balanced truncation wherein a novel method, based on the complete separation of stable and unstable invariant subspaces of a Hamiltonian matrix, is used for solving two dual algebraic Riccati equations at the cost of essentially one. A fast-converging quadruple-shift bulge-chasing SR algorithm is also introduced for this purpose. Numerical examples confirm the quality of the reduced-order models over those from conventional schemes.link_to_subscribed_fulltex
Abstract — We present a parameterized model order reduction method based on singular values and matr...
We present a passivity-preserving balanced truncation model reduction method for differential-algebr...
An algorithm is developed for passivity preserving model reduction of LTI systems. The derivation is...
This paper presents two recently developed algorithms for efficient model order reduction. Both algo...
We present a novel model-order reduction (MOR) method for linear time-invariant systems that preserv...
The major concerns in state-of-the-art model reduction algorithms are: achieving accurate models of ...
A new model reduction method for circuit simulation is presented, which preserves passivity by inter...
This chapter offers an introduction to Model Order Reduction (MOR). It gives an overview on the meth...
Abstract—The major concerns in state-of-the-art model reduc-tion algorithms are: achieving accuratem...
This chapter offers an introduction to Model Order Reduction (MOR). It gives an overview on the meth...
A very fast Smith-method-based Newton algorithm is introduced for the solution of large-scale contin...
Abstract — Here, model reduction, based on balanced trun-cation, of stable and passive systems will ...
open2siWe explore order reduction techniques to solve the algebraic Riccati equation (ARE), and inve...
We propose an efficient implementation of the Balanced Truncation (BT) method for model order reduct...
We explore order reduction techniques to solve the algebraic Riccati equation (ARE), and investigate...
Abstract — We present a parameterized model order reduction method based on singular values and matr...
We present a passivity-preserving balanced truncation model reduction method for differential-algebr...
An algorithm is developed for passivity preserving model reduction of LTI systems. The derivation is...
This paper presents two recently developed algorithms for efficient model order reduction. Both algo...
We present a novel model-order reduction (MOR) method for linear time-invariant systems that preserv...
The major concerns in state-of-the-art model reduction algorithms are: achieving accurate models of ...
A new model reduction method for circuit simulation is presented, which preserves passivity by inter...
This chapter offers an introduction to Model Order Reduction (MOR). It gives an overview on the meth...
Abstract—The major concerns in state-of-the-art model reduc-tion algorithms are: achieving accuratem...
This chapter offers an introduction to Model Order Reduction (MOR). It gives an overview on the meth...
A very fast Smith-method-based Newton algorithm is introduced for the solution of large-scale contin...
Abstract — Here, model reduction, based on balanced trun-cation, of stable and passive systems will ...
open2siWe explore order reduction techniques to solve the algebraic Riccati equation (ARE), and inve...
We propose an efficient implementation of the Balanced Truncation (BT) method for model order reduct...
We explore order reduction techniques to solve the algebraic Riccati equation (ARE), and investigate...
Abstract — We present a parameterized model order reduction method based on singular values and matr...
We present a passivity-preserving balanced truncation model reduction method for differential-algebr...
An algorithm is developed for passivity preserving model reduction of LTI systems. The derivation is...