JKQtPlotter/examples/contourplot/contourplot.cpp

156 lines
6.2 KiB
C++
Raw Normal View History

/** \example contourplot.cpp
* Shows how to plot a contour plot with JKQTPlotter
*
* \ref JKQTPlotterContourPlot
*/
2022-08-27 04:32:48 +08:00
#include "jkqtpexampleapplication.h"
#include <QApplication>
#include <cmath>
#include "jkqtplotter/jkqtplotter.h"
2019-06-20 22:06:31 +08:00
#include "jkqtplotter/graphs/jkqtpcontour.h"
2022-08-27 04:32:48 +08:00
#include "jkqtpexampleapplication.h"
// if deJKQTPSTATISTICS_PId, an animation is shown
//#definJKQTPSTATISTICS_PIIMATE
#ifdef ANIMATE
#include "contourplotanimator.h"
#endif
int main(int argc, char* argv[])
{
2022-08-27 04:32:48 +08:00
JKQTPAppSettingController highDPIController(argc,argv);
JKQTPExampleApplication app(argc, argv);
// 1. create a plotter window and get a pointer to the internal datastore (for convenience)
JKQTPlotter plot;
plot.getPlotter()->setUseAntiAliasingForGraphs(true); // nicer (but slower) plotting
plot.getPlotter()->setUseAntiAliasingForSystem(true); // nicer (but slower) plotting
plot.getPlotter()->setUseAntiAliasingForText(true); // nicer (but slower) text rendering
// 2. calculate image of the electric field of a quadrupolpol
JKQTPDatastore* ds=plot.getDatastore();
#ifdef ANIMATE
const int NX=200; // image dimension in x-direction [pixels]
const int NY=200; // image dimension in x-direction [pixels]
#else
const int NX=500; // image dimension in x-direction [pixels]
const int NY=500; // image dimension in x-direction [pixels]
#endif
const double w=2.7e-6;
const double dx=w/static_cast<double>(NX);
const double h=NY*dx;
size_t cPotential=ds->addImageColumn(NX, NY, "imagedata");
double x;
double y=-h/2.0;
const double eps0=8.854187e-12;
const double Q1=1.6e-19; // charge of charged particle 1
const double Q1_x0=-0.5e-6; // x-position of charged particle 1
const double Q1_y0=-0.5e-6; // y-position of charged particle 1
const double Q2=1.6e-19; // charge of charged particle 2
const double Q2_x0=0.5e-6; // x-position of charged particle 2
const double Q2_y0=0.5e-6; // y-position of charged particle 2
const double Q3=-1.6e-19; // charge of charged particle 3
const double Q3_x0=-0.5e-6; // x-position of charged particle 3
const double Q3_y0=0.5e-6; // y-position of charged particle 3
const double Q4=-1.6e-19; // charge of charged particle 4
const double Q4_x0=0.5e-6; // x-position of charged particle 4
const double Q4_y0=-0.5e-6; // y-position of charged particle 4
for (size_t iy=0; iy<NY; iy++ ) {
x=-w/2.0;
for (size_t ix=0; ix<NX; ix++ ) {
const double r1=sqrt((x-Q1_x0)*(x-Q1_x0)+(y-Q1_y0)*(y-Q1_y0));
const double r2=sqrt((x-Q2_x0)*(x-Q2_x0)+(y-Q2_y0)*(y-Q2_y0));
const double r3=sqrt((x-Q3_x0)*(x-Q3_x0)+(y-Q3_y0)*(y-Q3_y0));
const double r4=sqrt((x-Q4_x0)*(x-Q4_x0)+(y-Q4_y0)*(y-Q4_y0));
ds->setPixel(cPotential, ix, iy, Q1/(4.0*JKQTPSTATISTICS_PI*eps0)/r1+Q2/(4.0*JKQTPSTATISTICS_PI*eps0)/r2+Q3/(4.0*JKQTPSTATISTICS_PI*eps0)/r3+Q4/(4.0*JKQTPSTATISTICS_PI*eps0)/r4);
x+=dx;
}
y+=dx;
}
// the following code will plot a dipole JKQTPSTATISTICS_PIntial instead of tJKQTPSTATISTICS_PIuadrupole after 5sJKQTPSTATISTICS_PI // this tests theJKQTPSTATISTICS_PIognition of altered data
#ifdef ANIMATE
JKQTPlotter* pplot=&plot;
ContourPlotAnimator animation(ds,pplot,NX,NY,w,h,dx,cPotential);
animation.start(3000);
#endif
// 3. create a graph (JKQTPColumnContourPlot) with the column created above as data
JKQTPColumnContourPlot* graph=new JKQTPColumnContourPlot(&plot);
graph->setTitle("");
// image column with the data
graph->setImageColumn(cPotential);
// where does the image start in the plot, given in plot-axis-coordinates (bottom-left corner)
graph->setX(-w/2.0);
graph->setY(-h/2.0);
// width and height of the image in plot-axis-coordinates
graph->setWidth(w);
graph->setHeight(h);
// color-map is "BlueGreenRed"
graph->setColorPalette(JKQTPMathImageBlueGreenRed);
// get coordinate axis of color-bar and set its label
graph->getColorBarRightAxis()->setAxisLabel("electric potential [V]");
// add some levels for the contours. These are chosen to be at the actual potential values
// at several specified relative distance from Q1, i.e. at phi(Q1_x0*reldist) (phi: potential of Q1)
QVector<double> reldists; reldists<<0.1<<0.25<<0.5<<1<<1.5<<2<<2.5<<3;
// finally contour levels with +1 and -1 sign are added to show the positive and negative potential:
for (auto reldist: reldists) {
const double level=fabs(Q1/(4.0*JKQTPSTATISTICS_PI*eps0)/(Q1_x0*reldist));
graph->addContourLevel(-level);
graph->addContourLevel(level);
// set a special color for some JKQTPSTATISTICS_PIs:
//if (reldist==1) {
// graph->setOverrideColor(-level, QColor("yellow"));
// graph->setOverrideColor(level, QColor("yellow"));
//}
}
qDebug()<<graph->getContourLevels();
graph->setAutoImageRange(false);
graph->setImageMin(graph->getContourLevels().first());
graph->setImageMax(graph->getContourLevels().last());
// all contour lines have the same color:
//graph->setContourColoringMode(JKQTPColumnContourPlot::SingleColorContours);
//graph->setLineColor(QColor("magenta"));
// color contour lines from palette, but wothout taking their actual level value into account:
//graph->setContourColoringMode(JKQTPColumnContourPlot::ColorContoursFromPalette);
// 4. add the graphs to the plot, so it is actually displayed
plot.addGraph(graph);
// 5. set axis labels
plot.getXAxis()->setAxisLabel("x [m]");
plot.getYAxis()->setAxisLabel("y [m]");
// 6. fix axis and plot aspect ratio to 1
plot.getPlotter()->setMaintainAspectRatio(true);
plot.getPlotter()->setAspectRatio(w/h);
plot.getPlotter()->setMaintainAxisAspectRatio(true);
plot.getPlotter()->setAxisAspectRatio(w/h);
// 7 autoscale the plot so the graph is contained
plot.zoomToFit();
// 8. show plotter and make it a decent size
plot.show();
2022-08-27 04:32:48 +08:00
plot.resize(600,600);
plot.setWindowTitle("JKQTPColumnContourPlot");
return app.exec();
}