148 lines
5.0 KiB
C++
148 lines
5.0 KiB
C++
/**********************************************************
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This software is part of J.-S. Caux's ABACUS library.
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Copyright (c).
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-----------------------------------------------------------
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File: LiebLin_Fourier_to_x_equal_t.cc
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Purpose: Fourier transform to static space correlator for LiebLin.
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***********************************************************/
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#include "JSC.h"
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using namespace std;
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using namespace JSC;
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int main(int argc, char* argv[])
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{
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if (argc != 9) { // provide some info
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cout << endl << "Welcome to ABACUS++\t(copyright J.-S. Caux)." << endl;
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cout << endl << "Usage of LiebLin_Fourier_to_x_equal_t executable: " << endl;
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cout << endl << "Provide the following arguments:" << endl << endl;
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cout << "char whichDSF \t\t Which structure factor ? Options are: d for rho rho, g for psi psi{dagger}, o for psi{dagger} psi" << endl;
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cout << "DP c_int \t\t Value of the interaction parameter" << endl;
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cout << "DP L \t\t\t Length of the system" << endl;
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cout << "int N \t\t\t Number of particles" << endl;
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cout << "int iKmin" << endl << "int iKmax \t\t Min and max momentum integers scanned over" << endl;
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//cout << "DP kBT \t\t Temperature" << endl;
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cout << "RAW file name" << endl;
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cout << "int Npts_x Number of points in space for the Fourier transform" << endl;
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}
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else { // (argc == 9), correct nr of arguments
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char whichDSF = *argv[1];
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DP c_int = atof(argv[2]);
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DP L = atof(argv[3]);
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int N = atoi(argv[4]);
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int iKmin = atoi(argv[5]);
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int iKmax = atoi(argv[6]);
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//DP kBT = atof(argv[7]);
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char* rawfilename = argv[7];
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int Npts_x = atoi(argv[8]);
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// Force Npts_x
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//Npts_x = L;
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//stringstream filenameprefix;
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//Data_File_Name (filenameprefix, whichDSF, c_int, L, N, iKmin, iKmax, kBT, 0.0, "");
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//string prefix = filenameprefix.str();
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//stringstream RAW_stringstream; string RAW_string;
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//RAW_stringstream << prefix << ".raw";
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//RAW_string = RAW_stringstream.str(); const char* RAW_Cstr = RAW_string.c_str();
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ifstream RAW_infile;
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//RAW_infile.open(RAW_Cstr);
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RAW_infile.open(rawfilename);
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if (RAW_infile.fail()) {
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//cout << RAW_Cstr << endl;
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cout << rawfilename << endl;
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JSCerror("Could not open RAW_infile... ");
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}
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// Define the output file name: use the RAW file name but with different suffix
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stringstream SFT_stringstream; string SFT_string;
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SFT_stringstream << rawfilename << "_sft";
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SFT_string = SFT_stringstream.str(); const char* SFT_Cstr = SFT_string.c_str();
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ofstream SFT_outfile;
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SFT_outfile.open(SFT_Cstr);
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if (SFT_outfile.fail()) JSCerror("Could not open SFT_outfile... ");
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// First compute the static structure factor from the RAW data:
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Vect_DP SSF(0.0, iKmax - iKmin + 1);
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DP omega;
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int iK;
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DP FF;
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//int conv;
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DP dev;
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string label;
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while (RAW_infile.peek() != EOF) {
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RAW_infile >> omega >> iK >> FF >> dev >> label;
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if (iK >= iKmin && iK <= iKmax) {
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SSF[iK - iKmin] += FF * FF;
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}
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}
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RAW_infile.close();
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// Reset proper normalization:
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DP normalization = twoPI * L;
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for (int iK = 0; iK < iKmax - iKmin + 1; ++iK) SSF[iK] *= normalization/twoPI; // twoPI from integral over omega
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// Now define real-space coordinates: between 0 and L
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Vect_DP xlattice(Npts_x);
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for (int i = 0; i < Npts_x; ++i) xlattice[i] = (i + 0.5) * L/Npts_x;
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// Now the correlation at x:
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Vect_DP FTre(0.0, Npts_x);
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Vect_DP FTim(0.0, Npts_x);
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DP twopioverL = twoPI/L;
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// Fourier transform:
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for (int ix = 0; ix < Npts_x; ++ix) {
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for (int iK = iKmin; iK <= iKmax; ++iK) {
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FTre[ix] += SSF[iK - iKmin] * cos(twopioverL * iK * xlattice[ix]);
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FTim[ix] += SSF[iK - iKmin] * sin(twopioverL * iK * xlattice[ix]);
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}
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// Reset proper normalization: 1/L from space FT,
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FTre[ix] /= L;
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FTim[ix] /= L;
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// Outside of window iKmin, iKmax, we take the DSF to be a constant with delta function
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// at free energy k^2, so DSF = 2\pi N/L \delta(\omega - k^2) (to fit f-sumrule)
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// so SSF becomes N/L.
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// We thus need to correct above by adding
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// \frac{1}{L} \sum_{-\infty}^{iKmin - 1} SSF e^{ikx} + \frac{1}{L} \sum_{iKmax + 1}^\infty SSF e^{ikx}
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// Resumming carefully:
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//if (whichDSF == 'd') {
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//FTre[ix] += (sin(twopioverL * (iKmin - 0.5) * xlattice[ix]) - sin(twopioverL * (iKmax + 0.5) * xlattice[ix]))
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// * N/(2.0 * L*L * sin(PI * xlattice[ix]/L));
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//FTim[ix] += (-cos(twopioverL * (iKmin - 0.5) * xlattice[ix]) + cos(twopioverL * (iKmax + 0.5) * xlattice[ix]))
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// * N/(2.0 * L*L * sin(PI * xlattice[ix]/L));
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//}
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}
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// Output to file:
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for (int ix = 0; ix < Npts_x; ++ix) {
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if (ix > 0) SFT_outfile << endl;
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//SFT_outfile << xlattice[ix] << "\t" << FTre[ix] << "\t" << FTim[ix] << "\t" << FTreavg[ix] << "\t" << FTimavg[ix];
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SFT_outfile << xlattice[ix] << "\t" << FTre[ix] << "\t" << FTim[ix];
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}
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SFT_outfile.close();
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}
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return(0);
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}
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