Add to ORKGWe have developed an algorithm for the estimation of eigenvalue spectra and have applied it to the determination of the density of states in a photonic crystal, which requires the repeated solution of a generalized eigenvalue problem. We demonstrate that the algorithm offers significant advantages in time, memory, and ease of parallelization over conventional subspace iteration algorithms. In particular it is possible to obtain more than two orders of magnitude speedup in time over subspace methods for modestly sized matrices. For larger matrices the savings are even greater, whilst retaining accurate resolution of features of the eigenspectru
In this chapter, we describe various approaches to computing the spectra of photonic qua-sicrystals ...
We present a greedy algorithm for computing selected eigenpairs of a large sparse matrix $H$ that ca...
A quantum algorithm solves computational tasks using fewer physical resources than the best-known cl...
In this thesis three methods are presented which calculate the lowest eigenvalues of a set of extrem...
We consider PDE eigenvalue problems as they occur in two-dimensional photonic crystal modeling. If t...
This paper considers the numerical computation of the photonic band structure of periodic materials ...
We present a fast and efficient full vectorial modeling method for photonic crystal devices. This me...
Quantum computers promise to efficiently solve important problems that are intractable on a conventi...
Photonic crystals are a novel class of optical materials that, almost certainly, will underpin major...
Recently a novel family of eigensolvers, called spectral indicator methods (SIMs), was proposed. Giv...
We discuss density of states functions for photonic crystals, in the context of the two-dimensional ...
We propose a new method for band structure calculation of photonic crystals. It can treat arbitraril...
The first part of this paper is devoted to the approximative solution of linear and Hermitian eigenv...
An efficient semi-analytic method is developed for computing the band struc-tures of two-dimensional...
textA simulation study of the modes of propagation through a 3D photonic crystal using a C++ eigen v...
In this chapter, we describe various approaches to computing the spectra of photonic qua-sicrystals ...
We present a greedy algorithm for computing selected eigenpairs of a large sparse matrix $H$ that ca...
A quantum algorithm solves computational tasks using fewer physical resources than the best-known cl...
In this thesis three methods are presented which calculate the lowest eigenvalues of a set of extrem...
We consider PDE eigenvalue problems as they occur in two-dimensional photonic crystal modeling. If t...
This paper considers the numerical computation of the photonic band structure of periodic materials ...
We present a fast and efficient full vectorial modeling method for photonic crystal devices. This me...
Quantum computers promise to efficiently solve important problems that are intractable on a conventi...
Photonic crystals are a novel class of optical materials that, almost certainly, will underpin major...
Recently a novel family of eigensolvers, called spectral indicator methods (SIMs), was proposed. Giv...
We discuss density of states functions for photonic crystals, in the context of the two-dimensional ...
We propose a new method for band structure calculation of photonic crystals. It can treat arbitraril...
The first part of this paper is devoted to the approximative solution of linear and Hermitian eigenv...
An efficient semi-analytic method is developed for computing the band struc-tures of two-dimensional...
textA simulation study of the modes of propagation through a 3D photonic crystal using a C++ eigen v...
In this chapter, we describe various approaches to computing the spectra of photonic qua-sicrystals ...
We present a greedy algorithm for computing selected eigenpairs of a large sparse matrix $H$ that ca...
A quantum algorithm solves computational tasks using fewer physical resources than the best-known cl...