Loading doc/Section_howto.html +8 −4 Original line number Diff line number Diff line Loading @@ -320,6 +320,10 @@ place: <A NAME = "4_6"></A><H4>4.6 Granular models </H4> <P>Granular system are composed of spherical particles with a diameter, as opposed to point particles. This means they have an angular velocity and torque can be imparted to them to cause them to rotate. </P> <P>To run a simulation of a granular model, you will want to use the following commands: </P> Loading @@ -331,10 +335,11 @@ the following commands: </P> <UL><LI><A HREF = "compute_erotate_sphere.html">compute erotate/sphere</A> </UL> <P>will calculate rotational kinetic energy which can then be <A HREF = "">output with thermodynamic info</A>. <P>calculates rotational kinetic energy which can be <A HREF = "Section_howto.html#4_15">output with thermodynamic info</A>. </P> <P>Use one of these 3 pair potentials: <P>Use one of these 3 pair potentials, which compute forces and torques between interacting pairs of particles: </P> <UL><LI><A HREF = "pair_style.html">pair_style</A> gran/history <LI><A HREF = "pair_style.html">pair_style</A> gran/no_history Loading @@ -343,7 +348,6 @@ with thermodynamic info</A>. <P>These commands implement fix options specific to granular systems: </P> <UL><LI><A HREF = "fix_freeze.html">fix freeze</A> <LI><A HREF = "fix_gran_diag.html">fix gran/diag</A> <LI><A HREF = "fix_pour.html">fix pour</A> <LI><A HREF = "fix_viscous.html">fix viscous</A> <LI><A HREF = "fix_wall_gran.html">fix wall/gran</A> Loading doc/Section_howto.txt +8 −4 Original line number Diff line number Diff line Loading @@ -316,6 +316,10 @@ temper 100000 100 $t myfix 3847 58382 :pre 4.6 Granular models :link(4_6),h4 Granular system are composed of spherical particles with a diameter, as opposed to point particles. This means they have an angular velocity and torque can be imparted to them to cause them to rotate. To run a simulation of a granular model, you will want to use the following commands: Loading @@ -327,10 +331,11 @@ This compute "compute erotate/sphere"_compute_erotate_sphere.html :ul will calculate rotational kinetic energy which can then be "output with thermodynamic info"_. calculates rotational kinetic energy which can be "output with thermodynamic info"_Section_howto.html#4_15. Use one of these 3 pair potentials: Use one of these 3 pair potentials, which compute forces and torques between interacting pairs of particles: "pair_style"_pair_style.html gran/history "pair_style"_pair_style.html gran/no_history Loading @@ -339,7 +344,6 @@ Use one of these 3 pair potentials: These commands implement fix options specific to granular systems: "fix freeze"_fix_freeze.html "fix gran/diag"_fix_gran_diag.html "fix pour"_fix_pour.html "fix viscous"_fix_viscous.html "fix wall/gran"_fix_wall_gran.html :ul Loading Loading
doc/Section_howto.html +8 −4 Original line number Diff line number Diff line Loading @@ -320,6 +320,10 @@ place: <A NAME = "4_6"></A><H4>4.6 Granular models </H4> <P>Granular system are composed of spherical particles with a diameter, as opposed to point particles. This means they have an angular velocity and torque can be imparted to them to cause them to rotate. </P> <P>To run a simulation of a granular model, you will want to use the following commands: </P> Loading @@ -331,10 +335,11 @@ the following commands: </P> <UL><LI><A HREF = "compute_erotate_sphere.html">compute erotate/sphere</A> </UL> <P>will calculate rotational kinetic energy which can then be <A HREF = "">output with thermodynamic info</A>. <P>calculates rotational kinetic energy which can be <A HREF = "Section_howto.html#4_15">output with thermodynamic info</A>. </P> <P>Use one of these 3 pair potentials: <P>Use one of these 3 pair potentials, which compute forces and torques between interacting pairs of particles: </P> <UL><LI><A HREF = "pair_style.html">pair_style</A> gran/history <LI><A HREF = "pair_style.html">pair_style</A> gran/no_history Loading @@ -343,7 +348,6 @@ with thermodynamic info</A>. <P>These commands implement fix options specific to granular systems: </P> <UL><LI><A HREF = "fix_freeze.html">fix freeze</A> <LI><A HREF = "fix_gran_diag.html">fix gran/diag</A> <LI><A HREF = "fix_pour.html">fix pour</A> <LI><A HREF = "fix_viscous.html">fix viscous</A> <LI><A HREF = "fix_wall_gran.html">fix wall/gran</A> Loading
doc/Section_howto.txt +8 −4 Original line number Diff line number Diff line Loading @@ -316,6 +316,10 @@ temper 100000 100 $t myfix 3847 58382 :pre 4.6 Granular models :link(4_6),h4 Granular system are composed of spherical particles with a diameter, as opposed to point particles. This means they have an angular velocity and torque can be imparted to them to cause them to rotate. To run a simulation of a granular model, you will want to use the following commands: Loading @@ -327,10 +331,11 @@ This compute "compute erotate/sphere"_compute_erotate_sphere.html :ul will calculate rotational kinetic energy which can then be "output with thermodynamic info"_. calculates rotational kinetic energy which can be "output with thermodynamic info"_Section_howto.html#4_15. Use one of these 3 pair potentials: Use one of these 3 pair potentials, which compute forces and torques between interacting pairs of particles: "pair_style"_pair_style.html gran/history "pair_style"_pair_style.html gran/no_history Loading @@ -339,7 +344,6 @@ Use one of these 3 pair potentials: These commands implement fix options specific to granular systems: "fix freeze"_fix_freeze.html "fix gran/diag"_fix_gran_diag.html "fix pour"_fix_pour.html "fix viscous"_fix_viscous.html "fix wall/gran"_fix_wall_gran.html :ul Loading
