Add to ORKGWe present a new time-stepping criterion for N-body simulations that is based on the true dynamical time of a particle. This allows us to follow the orbits of particles correctly in all environments since it has better adaptivity than previous time-stepping criteria used in N-body simulations. Furthermore, it requires far fewer force evaluations in low-density regions of the simulation and has no dependence on artificial parameters such as, for example, the softening length. This can be orders of magnitude faster than conventional ad hoc methods that employ combinations of acceleration and softening and is ideally suited for hard problems, such as obtaining the correct dynamics in the very central regions of dark matter haloes. We also deri...
We present a new scheme to compensate for the small-scales approximations resulting from Particle-Me...
Astrophysical research in recent decades has made significant progress thanks to the availability of...
We provide a novel and efficient algorithm for computing accelerations in theperiodic large-N-body p...
We present a new time-stepping criterion for N-body simulations that is based on the true dynamical ...
We describe a new adaptive time-step criterion for integrating gravitational motion, which uses the ...
The time-step criterion plays a crucial role in direct N-body codes. If not chosen carefully, it wil...
AbstractSpecial high-accuracy direct force summation N-body algorithms and their relevance for the s...
The large dynamic range in some astrophysical N-body problems led to the use of adaptive multi-time-...
We study the accumulation of errors in cosmological N-body algorithms that are caused by representin...
Computational efficiency demands discretized, hierarchically organized and individually adaptive tim...
We describe the keys to meeting the challenges of N-body simulation: adaptive potential solvers, ad...
This paper describes a novel fourth-order integration algorithm for the gravitational N-body problem...
This paper presents a fast, economical particle-multiple-mesh N-body code optimized for large-N mode...
AbstractThe tree method is a widely implemented algorithm for collisionless N-body simulations in as...
We introduce and demonstrate the power of a method to speed up current iterative techniques for N-bo...
We present a new scheme to compensate for the small-scales approximations resulting from Particle-Me...
Astrophysical research in recent decades has made significant progress thanks to the availability of...
We provide a novel and efficient algorithm for computing accelerations in theperiodic large-N-body p...
We present a new time-stepping criterion for N-body simulations that is based on the true dynamical ...
We describe a new adaptive time-step criterion for integrating gravitational motion, which uses the ...
The time-step criterion plays a crucial role in direct N-body codes. If not chosen carefully, it wil...
AbstractSpecial high-accuracy direct force summation N-body algorithms and their relevance for the s...
The large dynamic range in some astrophysical N-body problems led to the use of adaptive multi-time-...
We study the accumulation of errors in cosmological N-body algorithms that are caused by representin...
Computational efficiency demands discretized, hierarchically organized and individually adaptive tim...
We describe the keys to meeting the challenges of N-body simulation: adaptive potential solvers, ad...
This paper describes a novel fourth-order integration algorithm for the gravitational N-body problem...
This paper presents a fast, economical particle-multiple-mesh N-body code optimized for large-N mode...
AbstractThe tree method is a widely implemented algorithm for collisionless N-body simulations in as...
We introduce and demonstrate the power of a method to speed up current iterative techniques for N-bo...
We present a new scheme to compensate for the small-scales approximations resulting from Particle-Me...
Astrophysical research in recent decades has made significant progress thanks to the availability of...
We provide a novel and efficient algorithm for computing accelerations in theperiodic large-N-body p...