#ifndef DATASMOOTHER_H
#define DATASMOOTHER_H
#include <list>
#include <stdio.h>
#include <math.h>
#include <values.h>
#include "gmapping/utils/stat.h"
#include <assert.h>
namespace GMapping {
class DataSmoother {
public:
struct DataPoint {
DataPoint(double _x=0.0, double _y=0.0) { x=_x;y=_y;}
double x;
double y;
};
typedef std::vector<DataPoint> Data;
DataSmoother(double parzenWindow) {
init(parzenWindow);
};
virtual ~DataSmoother() {
m_data.clear();
m_cummulated.clear();
};
void init(double parzenWindow) {
m_data.clear();
m_cummulated.clear();
m_int=-1;
m_parzenWindow = parzenWindow;
m_from = MAXDOUBLE;
m_to = -MAXDOUBLE;
m_lastStep = 0.001;
};
double sqr(double x) {
return x*x;
}
void setMinToZero() {
double minval=MAXDOUBLE;
for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) {
const DataPoint& d = *it;
if (minval > d.y)
minval = d.y;
}
for (Data::iterator it = m_data.begin(); it != m_data.end(); it++) {
DataPoint& d = *it;
d.y = d.y - minval;
}
m_cummulated.clear();
}
void add(double x, double p) {
m_data.push_back(DataPoint(x,p));
m_int=-1;
if (x-3.0*m_parzenWindow < m_from)
m_from = x - 3.0*m_parzenWindow;
if (x+3.0*m_parzenWindow > m_to)
m_to = x + 3.0*m_parzenWindow;
m_cummulated.clear();
}
void integrate(double step) {
m_lastStep = step;
double sum=0;
for (double x=m_from; x<=m_to; x+=step)
sum += smoothedData(x)*step;
m_int = sum;
}
double integral(double step, double xTo) {
double sum=0;
for (double x=m_from; x<=xTo; x+=step)
sum += smoothedData(x)*step;
return sum;
}
double smoothedData(double x) {
assert( m_data.size() > 0 );
double p=0;
double sum_y=0;
for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) {
const DataPoint& d = *it;
double dist = fabs(x - d.x);
p += d.y * exp( -0.5 * sqr ( dist/m_parzenWindow ) );
sum_y += d.y;
}
double denom = sqrt(2.0 * M_PI) * (sum_y) * m_parzenWindow;
p *= 1./denom;
return p;
}
double sampleNumeric(double step) {
assert( m_data.size() > 0 );
if (m_int <0 || step != m_lastStep)
integrate(step);
double r = sampleUniformDouble(0.0, m_int);
double sum2=0;
for (double x=m_from; x<=m_to; x+=step) {
sum2 += smoothedData(x)*step;
if (sum2 > r)
return x-0.5*step;
}
return m_to;
}
void computeCummuated() {
assert( m_data.size() > 0 );
m_cummulated.resize(m_data.size());
std::vector<double>::iterator cit = m_cummulated.begin();
double sum=0;
for (Data::const_iterator it = m_data.begin(); it != m_data.end(); ++it) {
sum += it->y;
(*cit) = sum;
++cit;
}
}
double sample() {
assert( m_data.size() > 0 );
if (m_cummulated.size() == 0) {
computeCummuated();
}
double maxval = m_cummulated.back();
double random = sampleUniformDouble(0.0, maxval);
int nCum = (int) m_cummulated.size();
double sum=0;
int i=0;
while (i<nCum) {
sum += m_cummulated[i];
if (sum >= random) {
return m_data[i].x + sampleGaussian(m_parzenWindow);
}
i++;
}
assert(0);
}
void sampleMultiple(std::vector<double>& samples, int num) {
assert( m_data.size() > 0 );
samples.clear();
if (m_cummulated.size() == 0) {
computeCummuated();
}
double maxval = m_cummulated.back();
std::vector<double> randoms(num);
for (int i=0; i<num; i++)
randoms[i] = sampleUniformDouble(0.0, maxval);
std::sort(randoms.begin(), randoms.end());
int nCum = (int) m_cummulated.size();
double sum=0;
int i=0;
int j=0;
while (i<nCum && j < num) {
sum += m_cummulated[i];
while (sum >= randoms[j] && j < num) {
samples.push_back( m_data[i].x + sampleGaussian(m_parzenWindow) );
j++;
}
i++;
}
}
void approxGauss(double step, double* mean, double* sigma) {
assert( m_data.size() > 0 );
double sum=0;
double d=0;
*mean=0;
for (double x=m_from; x<=m_to; x+=step) {
d = smoothedData(x);
sum += d;
*mean += x*d;
}
*mean /= sum;
double var=0;
for (double x=m_from; x<=m_to; x+=step) {
d = smoothedData(x);
var += sqr(x-*mean) * d;
}
var /= sum;
*sigma = sqrt(var);
}
double gauss(double x, double mean, double sigma) {
return 1.0/(sqrt(2.0*M_PI)*sigma) * exp(-0.5 * sqr( (x-mean)/sigma));
}
double cramerVonMisesToGauss(double step, double mean, double sigma) {
double p=0;
double s=0;
double g=0;
double sint=0;
double gint=0;
for (double x=m_from; x<=m_to; x+=step) {
s = smoothedData(x);
sint += s * step;
g = gauss(x, mean, sigma);
gint += g * step;
p += sqr( (sint - gint) );
}
return p;
}
double kldToGauss(double step, double mean, double sigma) {
double p=0;
double d=0;
double g=0;
double sd=0;
double sg=0;
for (double x=m_from; x<=m_to; x+=step) {
d = 1e-10 + smoothedData(x);
g = 1e-10 + gauss(x, mean, sigma);
sd += d;
sg += g;
p += d * log(d/g);
}
sd *= step;
sg *= step;
if (fabs(sd-sg) > 0.1)
assert(0);
p *= step;
return p;
}
void gnuplotDumpData(FILE* fp) {
for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) {
const DataPoint& d = *it;
fprintf(fp, "%f %f\n", d.x, d.y);
}
}
void gnuplotDumpSmoothedData(FILE* fp, double step) {
for (double x=m_from; x<=m_to; x+=step)
fprintf(fp, "%f %f\n", x, smoothedData(x));
}
protected:
Data m_data;
std::vector<double> m_cummulated;
double m_int;
double m_lastStep;
double m_parzenWindow;
double m_from;
double m_to;
};
/* class DataSmoother3D { */
/* public: */
/* struct InputPoint { */
/* InputPoint(double _x=0.0, double _y=0.0, double _t=0.0) { x=_x;y=_y;t=_t;} */
/* double x; */
/* double y; */
/* double t; */
/* }; */
/* struct DataPoint { */
/* DataPoint(const InputPoint& _p, double _val=0.0;) { p=_p;val=_val;} */
/* InputPoint p; */
/* double val; */
/* }; */
/* typedef std::list<DataPoint> Data; */
/* DataSmoother(double parzenWindow) { */
/* m_int=-1; */
/* m_parzenWindow = parzenWindow; */
/* m_from = InputPoint(MAXDOUBLE,MAXDOUBLE,MAXDOUBLE); */
/* m_to = InputPoint(-MAXDOUBLE,-MAXDOUBLE,-MAXDOUBLE); */
/* }; */
/* virtual ~DataSmoother() { */
/* m_data.clear(); */
/* }; */
/* double sqr(double x) { */
/* return x*x; */
/* } */
/* void setMinToZero() { */
/* double minval=MAXDOUBLE; */
/* for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) { */
/* const DataPoint& d = *it; */
/* if (minval > d.val) */
/* minval = d.val; */
/* } */
/* for (Data::iterator it = m_data.begin(); it != m_data.end(); it++) { */
/* DataPoint& d = *it; */
/* d.val = d.val - minval; */
/* } */
/* } */
/* void add(double x, double y, double t, double v) { */
/* m_data.push_back(DataPoint(InputPoint(x,y,t),v)); */
/* m_int=-1; */
/* if (x-3.0*m_parzenWindow < m_from.x) */
/* m_from.x = x - 3.0*m_parzenWindow.x; */
/* if (x+3.0*m_parzenWindow.x > m_to.x) */
/* m_to.x = x + 3.0*m_parzenWindow.x; */
/* if (y-3.0*m_parzenWindow < m_from.y) */
/* m_from.y = y - 3.0*m_parzenWindow.y; */
/* if (y+3.0*m_parzenWindow.y > m_to.y) */
/* m_to.y = y + 3.0*m_parzenWindow.y; */
/* if (t-3.0*m_parzenWindow < m_from.t) */
/* m_from.t = t - 3.0*m_parzenWindow.t; */
/* if (t+3.0*m_parzenWindow.t > m_to.t) */
/* m_to.t = t + 3.0*m_parzenWindow.t; */
/* } */
/* void integrate(InputPoint step) { */
/* m_lastStep = step; */
/* double sum=0; */
/* for (double x=m_from.x; x<=m_to.x; x+=step.x) { */
/* for (double y=m_from.y; x<=m_to.y; y+=step.y) { */
/* for (double t=m_from.t; t<=m_to.t; t+=step.t) { */
/* sum += smoothedData(InputPoint(x,y,t)) * step.x * step.y * step.t; */
/* } */
/* } */
/* } */
/* m_int = sum; */
/* } */
/* double smoothedData(InputPoint pnt) { */
/* assert( m_data.size() > 0 ); */
/* double p=0; */
/* double sum_y=0; */
/* for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) { */
/* const DataPoint& d = *it; */
/* double u = sqr( (pnt.x-d.x)/m_parzenWindow.x) + */
/* sqr((pnt.y-d.y)/m_parzenWindow.y) + */
/* sqr((pnt.t-d.t)/m_parzenWindow.t); */
/* p += d.val * exp( -0.5 * u); */
/* sum_y += d.y; */
/* } */
/* double denom = sqr(m_parzenWindow.x)*sqr(m_parzenWindow.x)*sqr(m_parzenWindow.x) * (sum_y) * */
/* sqrt(sqr(m_parzenWindow.x) + sqr(m_parzenWindow.y) + sqr(m_parzenWindow.t)); */
/* p *= 1./denom; */
/* return p; */
/* } */
/* double sample(const InputPoint& step) { */
/* assert( m_data.size() > 0 ); */
/* if (m_int <0 || step != m_lastStep) */
/* integrate(step); */
/* double r = sampleUniformDouble(0.0, m_int); */
/* double sum2=0; */
/* for (double x=m_from; x<=m_to; x+=step) { */
/* sum2 += smoothedData(x)*step; */
/* if (sum2 > r) */
/* return x-0.5*step; */
/* } */
/* return m_to; */
/* } */
/* void gnuplotDumpData(FILE* fp) { */
/* for (Data::const_iterator it = m_data.begin(); it != m_data.end(); it++) { */
/* const DataPoint& d = *it; */
/* fprintf(fp, "%f %f %f %f\n", d.x, d.y, d.t, d.val); */
/* } */
/* } */
/* void gnuplotDumpSmoothedData(FILE* fp, double step) { */
/* for (double x=m_from; x<=m_to; x+=step) */
/* fprintf(fp, "%f %f %f %f\n", x, ,y, t, smoothedData(x,y,t)); */
/* } */
/* protected: */
/* Data m_data; */
/* vector<double> m_intdata; */
/* double m_int; */
/* double m_lastStep; */
/* double m_parzenWindow; */
/* double m_from; */
/* double m_to; */
/* }; */
}
#endif
