t_random random;
int a,b,c;
- double e,u;
+ double e;
double help;
t_3dvec p;
int count;
md.force=force_lennard_jones;
//md.potential=potential_harmonic_oscillator;
//md.force=force_harmonic_oscillator;
- md.cutoff=R_CUTOFF;
- md.cutoff_square=(R_CUTOFF*R_CUTOFF);
+ md.cutoff=R_CUTOFF*LC_SI;
+ md.cutoff_square=md.cutoff*md.cutoff;
md.pot_params=&lj;
//md.pot_params=&ho;
md.integrate=velocity_verlet;
//md.tau=TAU;
md.status=0;
md.visual=&vis;
+ /* dimensions of the simulation cell */
+ md.dim.x=a*LC_SI;
+ md.dim.y=b*LC_SI;
+ md.dim.z=c*LC_SI;
+
+ /* verlet list init */
+ // later integrated in moldyn_init function!
+ verlet_list_init(&md);
printf("setting thermal fluctuations (T=%f K)\n",md.t);
thermal_init(&md,&random,count);
e=get_e_kin(si,count);
printf("kinetic energy: %.40f [J]\n",e);
- printf("3/2 N k T = %.40f [J]\n",1.5*count*K_BOLTZMANN*md.t);
+ printf("3/2 N k T = %.40f [J] (T=%f [K])\n",
+ 1.5*count*K_BOLTZMANN*md.t,md.t);
/* check total momentum */
p=get_total_p(si,count);
printf("total momentum: %.30f [Ns]\n",v3_norm(&p));
- /* check potential energy */
+ /* potential paramters */
lj.sigma6=LJ_SIGMA_SI*LJ_SIGMA_SI;
help=lj.sigma6*lj.sigma6;
lj.sigma6*=help;
ho.equilibrium_distance=0.25*sqrt(3.0)*LC_SI;
ho.spring_constant=1.0;
- u=get_e_pot(&md);
-
- printf("potential energy: %.40f [J]\n",u);
- printf("total energy (1): %.40f [J]\n",e+u);
- printf("total energy (2): %.40f [J]\n",get_total_energy(&md));
-
- md.dim.x=a*LC_SI;
- md.dim.y=b*LC_SI;
- md.dim.z=c*LC_SI;
-
printf("estimated accurate time step: %.30f [s]\n",
estimate_time_step(&md,3.0,md.t));
/* close */
+ verlet_list_shutdown(&md);
+
rand_close(&random);
moldyn_shutdown(&md);