Add to ORKGIn the harmonic description of general relativity, the principle part of Einstein's equations reduces to 10 curved space wave equations for the componenets of the space-time metric. We present theorems regarding the stability of several evolution-boundary algorithms for such equations when treated in second order differential form. The theorems apply to a model black hole space-time consisting of a spacelike inner boundary excising the singularity, a timelike outer boundary and a horizon in between. These algorithms are implemented as stable, convergent numerical codes and their performance is compared in a 2-dimensional excision problem
We present a new many-parameter family of hyperbolic representations of Einstein’s equations, which ...
Current spectral simulations of Einstein's equations require writing the system in first-order form,...
Current spectral simulations of Einstein’s equations require writing the sys-tem in first-order form...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
We analyze the excision strategy for simulating black holes. The problem is modeled by the propagati...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
This project is focused on the numerical solutions of Einstein's equations, which de-scribe pro...
We use rigorous techniques from numerical analysis of hyperbolic equations in bounded domains to con...
We describe an explicit in time, finite-difference code designed to simulate black holes by using th...
We present a new many-parameter family of hyperbolic representations of Einstein’s equations, which ...
This work concerns the evolution of equations of general relativity; their mathematical properties a...
We describe an explicit in time, finite-difference code designed to simulate black holes by using th...
We present a new many-parameter family of hyperbolic representations of Einstein’s equations, which ...
Current spectral simulations of Einstein's equations require writing the system in first-order form,...
Current spectral simulations of Einstein’s equations require writing the sys-tem in first-order form...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
In the harmonic description of general relativity, the principle part of Einstein's equations reduce...
We analyze the excision strategy for simulating black holes. The problem is modeled by the propagati...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
We describe a numerical code that solves Einstein’s equations for a Schwarzschild black hole in sphe...
This project is focused on the numerical solutions of Einstein's equations, which de-scribe pro...
We use rigorous techniques from numerical analysis of hyperbolic equations in bounded domains to con...
We describe an explicit in time, finite-difference code designed to simulate black holes by using th...
We present a new many-parameter family of hyperbolic representations of Einstein’s equations, which ...
This work concerns the evolution of equations of general relativity; their mathematical properties a...
We describe an explicit in time, finite-difference code designed to simulate black holes by using th...
We present a new many-parameter family of hyperbolic representations of Einstein’s equations, which ...
Current spectral simulations of Einstein's equations require writing the system in first-order form,...
Current spectral simulations of Einstein’s equations require writing the sys-tem in first-order form...