Mercurial > hg > ltpda
view src/ltpda_dft/ltpda_dft.c @ 52:daf4eab1a51e database-connection-manager tip
Fix. Default password should be [] not an empty string
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Wed, 07 Dec 2011 17:29:47 +0100 |
parents | f0afece42f48 |
children |
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/* * Mex file that implements the core DFT part of the LPSD algorithm. * * M Hewitson 15-01-08 * * $Id: ltpda_dft.c,v 1.16 2009/08/18 10:53:27 hewitson Exp $ */ #include <math.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <mex.h> #include "ltpda_dft.h" #include "version.h" #include "../c_sources/polyreg.c" #define DEBUG 0 /* * Rounding function * */ int myround(double x) { return ((int) (floor(x + 0.5))); } /* * Matlab mex file to make a dft at a single frequency * * Inputs * - data * - seg length * - DFT coefficients * - overlap (%) * - order of detrending * * function [P, navs] = ltpda_dft(x, seglen, DFTcoeffs, olap, order); * */ void mexFunction( int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { /* Parse inputs */ if( (nrhs == 0) && (nlhs == 0) ) { print_usage(VERSION); return; } else if ( (nrhs == 5) && (nlhs == 3) ) /* let's go */ { double Pr, Vr; double *xdata, *Cr, *Ci; double olap; long int nData; long int nSegs; long int segLen; int order; double *ptr; if( !mxIsComplex(prhs[2]) ) mexErrMsgTxt("DFT coefficients must be complex.\n"); /* Extract inputs */ xdata = mxGetPr(prhs[0]); /* Pointer to data */ nData = mxGetNumberOfElements(prhs[0]); /* Number of data points */ segLen = (int)mxGetScalar(prhs[1]); /* Segment length */ Cr = mxGetPr(prhs[2]); /* Real part of DFT coefficients */ Ci = mxGetPi(prhs[2]); /* Imag part of DFT coefficients */ olap = mxGetScalar(prhs[3]); /* Overlap percentage */ order = (int)mxGetScalar(prhs[4]); /* Order of detrending */ if (order > 10 || order < -1) mexErrMsgTxt("Detrending order must be between -1 and 10"); /*mexPrintf("Input data: %d samples\n", nData);*/ /*mexPrintf("Segment length: %d\n", segLen);*/ /*mexPrintf("Overlap: %f\n", olap);*/ /* Compute DFT */ dft(&Pr, &Vr, &nSegs, xdata, nData, segLen, Cr, Ci, olap, order); /* Set output matrices */ plhs[0] = mxCreateDoubleMatrix(1, 1, mxCOMPLEX); plhs[1] = mxCreateDoubleMatrix(1, 1, mxCOMPLEX); plhs[2] = mxCreateDoubleMatrix(1, 1, mxCOMPLEX); /* Get pointers to output matrices */ ptr = mxGetPr(plhs[0]); ptr[0] = Pr; ptr = mxGetPr(plhs[1]); ptr[0] = Vr; ptr = mxGetPr(plhs[2]); ptr[0] = nSegs; } else if ( (nrhs == 6) && (nlhs == 5) ) /* let's go */ { double Mr, Mi, XX, YY, M2; double *xdata, *ydata, *Cr, *Ci; double olap; long int nData, nxData, nyData; long int nSegs; long int segLen; int order; double *ptr; if( !mxIsComplex(prhs[3]) ) mexErrMsgTxt("DFT coefficients must be complex.\n"); /* Extract inputs */ xdata = mxGetPr(prhs[0]); /* Pointer to data */ ydata = mxGetPr(prhs[1]); /* Pointer to data */ nxData = mxGetNumberOfElements(prhs[0]); /* Number of data points */ nyData = mxGetNumberOfElements(prhs[0]); /* Number of data points */ segLen = (int)mxGetScalar(prhs[2]); /* Segment length */ Cr = mxGetPr(prhs[3]); /* Real part of DFT coefficients */ Ci = mxGetPi(prhs[3]); /* Imag part of DFT coefficients */ olap = mxGetScalar(prhs[4]); /* Overlap percentage */ order = (int)mxGetScalar(prhs[5]); /* Order of detrending */ if (order > 10 || order < -1) mexErrMsgTxt("Detrending order must be between -1 and 10"); if (nxData != nyData) mexErrMsgTxt("The two input data vector should be the same length."); nData = nxData; /*mexPrintf("Input data: %d samples\n", nData);*/ /*mexPrintf("Segment length: %d\n", segLen);*/ /*mexPrintf("Overlap: %f\n", olap);*/ /* Compute DFT */ xdft(&Mr, &Mi, &XX, &YY, &M2, &nSegs, xdata, ydata, nData, segLen, Cr, Ci, olap, order); /* Set output matrices */ plhs[0] = mxCreateDoubleMatrix(1, 1, mxCOMPLEX); plhs[1] = mxCreateDoubleMatrix(1, 1, mxREAL); plhs[2] = mxCreateDoubleMatrix(1, 1, mxREAL); plhs[3] = mxCreateDoubleMatrix(1, 1, mxREAL); plhs[4] = mxCreateDoubleMatrix(1, 1, mxREAL); /* Get pointers to output matrices */ ptr = mxGetPr(plhs[0]); ptr[0] = Mr; ptr = mxGetPi(plhs[0]); ptr[0] = Mi; ptr = mxGetPr(plhs[1]); ptr[0] = XX; ptr = mxGetPr(plhs[2]); ptr[0] = YY; ptr = mxGetPr(plhs[3]); ptr[0] = M2; ptr = mxGetPr(plhs[4]); ptr[0] = nSegs; } else /* we have an error */ { print_usage(VERSION); mexErrMsgTxt("### incorrect usage"); } } /* * Output usage to MATLAB terminal * */ void print_usage(char *version) { mexPrintf("ltpda_dft version %s\n", version); mexPrintf(" usage: function [P, navs] = ltpda_dft(x, seglen, DFTcoeffs, olap, order); \n"); } /* * Short routine to compute the DFT at a single frequency * */ void dft(double *Pr, double *Vr, long int *Navs, double *xdata, long int nData, long int segLen, double *Cr, double *Ci, double olap, int order) { long int istart; double shift, start; double *px, *cr, *ci; double rxsum, ixsum; double Xr, Mr, M2, Qr; double p, *x, *a; long int jj, ii; /* Compute the number of averages we want here */ double ovfact = 1. / (1. - olap / 100.); double davg = ((double) ((nData - segLen)) * ovfact) / segLen + 1; long int navg = myround(davg); /* Compute steps between segments */ if (navg == 1) shift = 1; else shift = (double) (nData - segLen) / (double) (navg - 1); if (shift < 1) shift = 1; /* mexPrintf("Seglen: %d\t | Shift: %f\t | navs: %d\n", segLen, shift, navg);*/ /* allocate vectors */ x = (double*)mxCalloc(segLen, sizeof(double)); /* detrending output */ a = (double*)mxCalloc(order+1, sizeof(double)); /* detrending coefficients */ /* Loop over segments */ start = 0.0; Xr = 0.0; Qr = 0.0; Mr = 0.0; M2 = 0.0; for (ii = 0; ii < navg; ii++) { /* compute start index */ istart = myround(start); start += shift; /* pointer to start of this segment */ px = &(xdata[istart]); /* pointer to DFT coeffs */ cr = &(Cr[0]); ci = &(Ci[0]); /* Detrend segment */ switch (order) { case -1: /* no detrending */ memcpy(x, px, segLen*sizeof(double)); break; case 0: /* mean removal */ polyreg0(px, segLen, x, a); break; case 1: /* linear detrending */ polyreg1(px, segLen, x, a); break; case 2: /* 2nd order detrending */ polyreg2(px, segLen, x, a); break; case 3: /* 3rd order detrending */ polyreg3(px, segLen, x, a); break; case 4: /* 4th order detrending */ polyreg4(px, segLen, x, a); break; case 5: /* 5th order detrending */ polyreg5(px, segLen, x, a); break; case 6: /* 6th order detrending */ polyreg6(px, segLen, x, a); break; case 7: /* 7th order detrending */ polyreg7(px, segLen, x, a); break; case 8: /* 8th order detrending */ polyreg8(px, segLen, x, a); break; case 9: /* 9th order detrending */ polyreg9(px, segLen, x, a); break; case 10: /* 10th order detrending */ polyreg10(px, segLen, x, a); break; } /* Go over all samples in this segment */ rxsum = ixsum = 0.0; for (jj=0; jj<segLen; jj++) { p = x[jj]; rxsum += (*cr) * p; /* cos term */ ixsum += (*ci) * p; /* sin term */ /* increment pointers */ cr++; ci++; } /*mexPrintf(" xsum=(%g +i %g), ysum=(%g + i%g)\n", rxsum, ixsum, rysum, iysum);*/ /* Average the cross-power * Rsum += rxsum*rxsum + ixsum*ixsum; */ /* Welford's algorithm to update mean and variance */ if (ii == 0) { Mr = (rxsum*rxsum + ixsum*ixsum); } else { Xr = (rxsum*rxsum + ixsum*ixsum); Qr = Xr - Mr; Mr += Qr/ii; M2 += Qr * (Xr - Mr); } } /* mexPrintf(" start: %f \t istart: %d | %d \n", start, istart, nData-istart);*/ /*mexPrintf(" Rsum=%g, MR=%g \n", Rsum,MR); */ /* clean up */ mxFree(x); mxFree(a); /* Outputs */ *Pr = Mr; if(navg == 1){ *Vr = Mr*Mr; } else { *Vr = M2/(navg-1); } *Navs = navg; } /* * Short routine to compute the cross-DFT at a single frequency * */ void xdft(double *Pxyr, double *Pxyi, double *Pxx, double *Pyy, double *Vr, long int *Navs, double *xdata, double *ydata, long int nData, long int segLen, double *Cr, double *Ci, double olap, int order) { long int istart; double shift, start; double *px, *py, *cr, *ci; double rxsum, ixsum, rysum, iysum; double XYr, XYi, QXYr, QXYi, QXYrn, QXYin; double MXYr, MXYi, MXY2; double XX, YY, QXX, QYY; double MXX, MYY, MXX2, MYY2; double p, *x, *y, *a; double ct, st; long int jj, ii; /* Compute the number of averages we want here */ double ovfact = 1. / (1. - olap / 100.); double davg = ((double) ((nData - segLen)) * ovfact) / segLen + 1; long int navg = myround( davg ); /* Compute steps between segments */ if (navg == 1) shift = 1; else shift = (double) (nData - segLen) / (double) (navg - 1); if (shift < 1) shift = 1; /* mexPrintf("Seglen: %d\t | Shift: %f\t | navs: %d\n", segLen, shift, navg); */ /* allocate vectors */ y = (double*)mxCalloc(segLen, sizeof(double)); /* detrending output */ x = (double*)mxCalloc(segLen, sizeof(double)); /* detrending output */ a = (double*)mxCalloc(order+1, sizeof(double)); /* detrending coefficients */ /* Loop over segments */ start = 0.0; MXYr = 0.0; MXYi = 0.0; MXY2 = 0.0; MXX = 0.0; MYY = 0.0; MXX2 = 0.0; MYY2 = 0.0; for (ii = 0; ii < navg; ii++) { /* compute start index */ istart = myround(start); start += shift; /* pointer to start of this segment */ px = &(xdata[istart]); py = &(ydata[istart]); /* pointer to DFT coeffs */ cr = &(Cr[0]); ci = &(Ci[0]); /* Detrend segment */ switch (order) { case -1: /* no detrending */ memcpy(x, px, segLen*sizeof(double)); memcpy(y, py, segLen*sizeof(double)); break; case 0: /* mean removal */ polyreg0(px, segLen, x, a); polyreg0(py, segLen, y, a); break; case 1: /* linear detrending */ polyreg1(px, segLen, x, a); polyreg1(py, segLen, y, a); break; case 2: /* 2nd order detrending */ polyreg2(px, segLen, x, a); polyreg2(py, segLen, y, a); break; case 3: /* 3rd order detrending */ polyreg3(px, segLen, x, a); polyreg3(py, segLen, y, a); break; case 4: /* 4th order detrending */ polyreg4(px, segLen, x, a); polyreg4(py, segLen, y, a); break; case 5: /* 5th order detrending */ polyreg5(px, segLen, x, a); polyreg5(py, segLen, y, a); break; case 6: /* 6th order detrending */ polyreg6(px, segLen, x, a); polyreg6(py, segLen, y, a); break; case 7: /* 7th order detrending */ polyreg7(px, segLen, x, a); polyreg7(py, segLen, y, a); break; case 8: /* 8th order detrending */ polyreg8(px, segLen, x, a); polyreg8(py, segLen, y, a); break; case 9: /* 9th order detrending */ polyreg9(px, segLen, x, a); polyreg9(py, segLen, y, a); break; case 10: /* 10th order detrending */ polyreg10(px, segLen, x, a); polyreg10(py, segLen, y, a); break; } /* Go over all samples in this segment */ rxsum = ixsum = 0.0; rysum = iysum = 0.0; for (jj=0; jj<segLen; jj++) { ct = (*cr); st = (*ci); p = x[jj]; rxsum += ct * p; /* cos term */ ixsum += st * p; /* sin term */ p = y[jj]; rysum += ct * p; /* cos term */ iysum += st * p; /* sin term */ /* increment pointers */ cr++; ci++; } /*mexPrintf(" xsum=(%g +i %g), ysum=(%g + i%g)\n", rxsum, ixsum, rysum, iysum);*/ /* Average XX and YY power * XXsum += rxsum*rxsum + ixsum*ixsum; * YYsum += rysum*rysum + iysum*iysum; * XYRsum += rysum*rxsum + iysum*ixsum; * XYIsum += iysum*rxsum - rysum*ixsum; */ /* Welford's algorithm to update mean and variance for cross-power */ if (ii == 0) { /* for XY */ MXYr = rysum*rxsum + iysum*ixsum; MXYi = iysum*rxsum - rysum*ixsum; /* for XX */ MXX = rxsum*rxsum + ixsum*ixsum; /* for YY */ MYY = rysum*rysum + iysum*iysum; } else { /* for XY cross - power */ XYr = rysum*rxsum + iysum*ixsum; XYi = iysum*rxsum - rysum*ixsum; QXYr = XYr - MXYr; QXYi = XYi - MXYi; MXYr += QXYr/ii; MXYi += QXYi/ii; /* new Qs, using new mean */ QXYrn = XYr - MXYr; QXYin = XYi - MXYi; /* taking abs to get real variance */ MXY2 += sqrt(pow(QXYr * QXYrn - QXYi * QXYin, 2) + pow(QXYr * QXYin + QXYi * QXYrn, 2)); /* for XX */ XX = rxsum*rxsum + ixsum*ixsum; QXX = XX - MXX; MXX += QXX/ii; MXX2 += QXX*(XX - MXX); /* for YY */ YY = rysum*rysum + iysum*iysum; QYY = YY - MYY; MYY += QYY/ii; MYY2 += QYY*(YY - MYY); } } /* mexPrintf(" start: %f \t istart: %d | %d \n", start, istart, nData-istart);*/ /*mexPrintf(" Rsum=%g, Isum=%g\n", Rsum, Isum);*/ /* clean up */ mxFree(y); mxFree(x); mxFree(a); /* Outputs */ *Pxyr = MXYr; *Pxyi = MXYi; if(navg == 1){ *Vr = MXYr*MXYr; /* set to mean^2 here, but at the end returns Inf in the ao.dy field */ } else { *Vr = MXY2/(navg-1); } *Pxx = MXX; *Pyy = MYY; /* we don't return variance for XX and YY */ *Navs = navg; } /* * Fast linear detrending routine * */ void remove_linear_drift(double *segm, double *data, int nfft) { int i; long double sx, sy, stt, sty, a, b, xm; sx = (long double) nfft *(long double) (nfft - 1) / 2.0L; xm = (long double) (nfft - 1) / 2.0L; stt = ((long double) nfft * (long double) nfft * (long double) nfft - (long double) nfft) / 12.0L; sy=sty = 0; for (i = 0; i < nfft; i++) { sy += data[i]; sty += (i-xm) * data[i]; } b = sty / stt; a = (sy - sx * b) / nfft; for (i = 0; i < nfft; i++) { segm[i] = data[i] - (a + b * i); } }