def SW_Fexc(T, n): #return SW.fhs(T,n) #return SW.fdisp(T,n) return SW.fdisp(T, n) + SW.fhs(T, n)
def SW_Finfinity(n): T = 1.0e8 return SW.fhs(T, n) / T
colors = ['ro', 'go', 'bo', 'rx', 'gx', 'bx'] plt.figure() size = 15.0 for i in range(0, len(allFinfinity)): plt.plot(allFinfinity[i][0], allFinfinity[i][1], colors[i % len(colors)], label="L=%f" % allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("dataF-saftF") plt.legend(loc='best') plt.savefig("deltaF.pdf") plt.close() colors = ['ro', 'go', 'bo', 'rx', 'gx', 'bx'] plt.figure() size = 15.0 for i in range(0, len(allFinfinity)): #ms=size*(0.7)**i plt.plot(allFinfinityPercent[i][0], allFinfinityPercent[i][1], colors[i % len(colors)], label="L=%f" % allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("(dataF-saftF)/dataF*100.0") plt.legend(loc='best') plt.savefig("deltaFpercent.pdf") plt.close() print SW.fhs(0, 0.1) print SW.fhs(0, 0.2)
def SW_Finfinity(n): T=1.0e8 return SW.fhs(T,n)/T
def SW_Fexc(T,n): #return SW.fhs(T,n) #return SW.fdisp(T,n) return SW.fdisp(T,n)+SW.fhs(T,n)
allFinfinityPercent.append([[],[]]) for i in range(0,len(dataFreeEnergy)): allFinfinityPercent[-1][0].append(ffData[i]) allFinfinityPercent[-1][1].append(dataFreeEnergy[i]) ###############--------------all ww=1.5 T=infinity dataF-saftF------## colors=['ro','go','bo','rx','gx','bx'] plt.figure() size=15.0 for i in range(0,len(allFinfinity)): plt.plot(allFinfinity[i][0],allFinfinity[i][1],colors[i%len(colors)],label="L=%f"%allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("dataF-saftF") plt.legend(loc='best') plt.savefig("deltaF.pdf") plt.close() colors=['ro','go','bo','rx','gx','bx'] plt.figure() size=15.0 for i in range(0,len(allFinfinity)):#ms=size*(0.7)**i plt.plot(allFinfinityPercent[i][0],allFinfinityPercent[i][1],colors[i%len(colors)],label="L=%f"%allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("(dataF-saftF)/dataF*100.0") plt.legend(loc='best') plt.savefig("deltaFpercent.pdf") plt.close() print SW.fhs(0,0.1) print SW.fhs(0,0.2)
allFinfinityPercent.append([[], []]) for i in range(0, len(dataFreeEnergy)): allFinfinityPercent[-1][0].append(ffData[i]) allFinfinityPercent[-1][1].append(dataFreeEnergy[i]) ###############--------------all ww=1.5 T=infinity dataF-saftF------## colors=['ro', 'go', 'bo', 'rx', 'gx', 'bx'] plt.figure() size=15.0 for i in range(0, len(allFinfinity)): plt.plot(allFinfinity[i][0], allFinfinity[i][1], colors[i%len(colors)], label="L=%f"%allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("dataF-saftF") plt.legend(loc='best') plt.savefig("deltaF.pdf") plt.close() colors=['ro', 'go', 'bo', 'rx', 'gx', 'bx'] plt.figure() size=15.0 for i in range(0, len(allFinfinity)):#ms=size*(0.7)**i plt.plot(allFinfinityPercent[i][0], allFinfinityPercent[i][1], colors[i%len(colors)], label="L=%f"%allCellLength[i]) plt.xlabel("filling fraction") plt.ylabel("(dataF-saftF)/dataF*100.0") plt.legend(loc='best') plt.savefig("deltaFpercent.pdf") plt.close() print(SW.fhs(0, 0.1)) print(SW.fhs(0, 0.2))