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(Criou página com '<source lang = "c"> /**************************************************************************** * Lattice Gas Cst * *************************************...') |
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Linha 19: | Linha 19: | ||
#define RHO 0.25 | #define RHO 0.25 | ||
#define EPSILON (1.0) | #define EPSILON (1.0) | ||
#define TRAN | #define TRAN 100000 | ||
#define | #define TMAX 1000000 | ||
/**************************************************************************** | /**************************************************************************** | ||
* | * GLOBAL VARIABLES * | ||
***************************************************************************/ | ***************************************************************************/ | ||
int site[L2], neigh[L2][5]; | int site[L2], neigh[L2][5]; |
Edição atual tal como às 19h18min de 16 de agosto de 2020
/****************************************************************************
* Lattice Gas Cst *
***************************************************************************/
/****************************************************************************
* INCLUDES *
***************************************************************************/
#include<stdio.h>
#include<stdlib.h>
#include<math.h>
#include<time.h>
/****************************************************************************
* DEFINITIONS *
***************************************************************************/
#define L 64
#define L2 (L*L)
#define RHO 0.25
#define EPSILON (1.0)
#define TRAN 100000
#define TMAX 1000000
/****************************************************************************
* GLOBAL VARIABLES *
***************************************************************************/
int site[L2], neigh[L2][5];
int ET, dE;
int density;
double boltz[4];
/****************************************************************************
* FUNCTIONS *
***************************************************************************/
void initialize(double TEMP);
void monte_carlo_routine(void);
void update_neighbour(int k);
void density_function(void);
void gnu_plot(void);
/****************************************************************************
* MAIN PROGRAM *
***************************************************************************/
int main(int argc, char *argv[])
{
int mcs;
double TEMP;
char Arq1[100];
FILE *arq1;
TEMP = atof(argv[1]);
srand(time(NULL));
initialize(TEMP);
for(mcs=0; mcs<TRAN; mcs++)
{
monte_carlo_routine();
}
sprintf(Arq1, "series_T%.3lfL%d.dsf", TEMP, L);
arq1 = fopen(Arq1, "w");
fprintf(arq1, "#MCS\tET\tdensity\n");
for(mcs=0; mcs<TMAX; mcs++)
{
monte_carlo_routine();
density_function();
fprintf(arq1, "%d\t%d\t%d\n", mcs, ET, density);
#ifdef GNU
if(mcs%10 == 0)
{
printf("set title 'Tempo = %d MCS\n", mcs);
gnu_plot();
}
#endif
}
fclose(arq1);
return 0;
}
/****************************************************************************
* INITIALIZATION *
***************************************************************************/
void initialize(double TEMP)
{
int i, j;
boltz[1] = exp(-1.0/TEMP);
boltz[2] = exp(-2.0/TEMP);
boltz[3] = exp(-3.0/TEMP);
for(i=0; i<L2; i++)
{
site[i] = 0;
for(j=0; j<5; j++)
{
neigh[i][j] = 0;
}
}
for(i=0; i<(RHO*L2); i++)
{
j = rand()%L2;
site[j] = 1;
}
ET = 0;
density = 0;
for(i=0; i<L2; i++)
{
neigh[i][0] = (i-L+L2)%L2;
neigh[i][1] = (i+1)%L + (i/L)*L;
neigh[i][2] = (i+L)%L2;
neigh[i][3] = (i-1+L)%L + (i/L)*L;
for(j=0; j<4; j++)
{
neigh[i][4] += site[neigh[i][j]];
}
ET += site[i]*neigh[i][4];
density += site[i];
}
ET = -ET/2;
return;
}
/****************************************************************************
* MONTE CARLO ROUTINE *
***************************************************************************/
void monte_carlo_routine(void)
{
int i, j, k, t;
int s_i, s_j;
int sum_i, sum_j;
int site_aux;
int Ei, Ef;
double r, flip_prob;
for(t=0; t<L2; t++)
{
i = rand()%L2;
k = rand()%4;
j = neigh[i][k];
s_i = site[i];
s_j = site[j];
if(s_i != s_j)
{
sum_i = neigh[i][4];
sum_j = neigh[j][4];
Ei = -sum_i*s_i - sum_j*s_j;
sum_i = sum_i + s_i - s_j;
sum_j = sum_j + s_j - s_i;
Ef = -sum_i*s_j - sum_j*s_i;
dE = 0;
dE = Ef-Ei;
if(dE <= 0)
{
site_aux = site[i];
site[i] = site[j];
site[j] = site_aux;
ET += dE;
update_neighbour(i);
update_neighbour(j);
}
else
{
flip_prob = boltz[dE];
r = rand()/(double)RAND_MAX;
if(r < flip_prob)
{
site_aux = site[i];
site[i] = site[j];
site[j] = site_aux;
ET += dE;
update_neighbour(i);
update_neighbour(j);
}
}
}
}
return;
}
/****************************************************************************
* UPDATE NEIGHBOURS *
***************************************************************************/
void update_neighbour(int k)
{
int i;
for(i=0; i<4; i++)
{
neigh[neigh[k][i]][4] += 2*site[k] -1;
}
return;
}
/****************************************************************************
* DENSITY FUNCTION *
***************************************************************************/
void density_function(void)
{
int i;
density = 0;
for(i=0; i<L2; i++)
{
density += site[i];
}
return;
}
/****************************************************************************
* GNUPLOT VIEW *
***************************************************************************/
void gnu_plot(void)
{
int ii,jj;
printf("set xrange [0:%d]\nset yrange [0:%d]\n", (L-1), (L-1));
printf("set cbrange [0:4]\n");
printf("unset xtics\nunset ytics\n");
printf("set palette defined (0 'black', 1 'dark-violet')\n");
printf("unset colorbox\n");
printf("set size square\n");
printf("set key off\n");
printf("plot \"-\" matrix w image\n");
for(jj=0;jj<L;jj++)
{
for(ii=0;ii<L;ii++)
{
printf("%d ", site[ii + jj*L]);
}
printf("\n");
}
printf("\ne\n pause 0.1\n");
return;
}