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69ad2a0182
- improved documentation - changed: using static const variables instead of \c #define for fixed default values (e.g. JKQTPImageTools::LUTSIZE, JKQTPImageTools::PALETTE_ICON_WIDTH, JKQTPlotterDrawinTools::ABS_MIN_LINEWIDTH, JKQTMathText::ABS_MIN_LINEWIDTH ...) - new: added debugging option, which surrounds different regions with visible rectangles (JKQTBasePlotter::enableDebugShowRegionBoxes() ) - fixed: colorbars at top were positioned over the plot label - new: frames (plot viewport, key/legend ...) may be rounded off at the corners - new: diverse new styling options (default font name/size ...) - speed improvements to JKQTMathText::useSTIX()
3.5 KiB
3.5 KiB
Example (JKQTPlotter): Plotting Geometric Objects
This project (see ./test/simpletest_geometric/
) shows the capabilities of JKQTPlotter to also draw geometric elements, like circles, ellipses, rectangles etc.
The source code of the main application can be found in jkqtplotter_simpletest_geometric.cpp
. First a plot is generated and the axis aspect ratio is set to 1, so an accurate plot is generated. Then several geometric graphs are added to the plot. Here are some examples, you can find more more examples in the source code of the example:
// a text element
plot.addGraph(new JKQTPGeoText(&plot, 0.1,0.6, "$x_{1/2}=\\frac{\\sqrt{b^2-4ac}}{2a}$", 10, QColor("red")));
// a single symbol
plot.addGraph(new JKQTPGeoSymbol(&plot, 0.1,0.6, JKQTPCircle, 5, QColor("grey")));
// a line
plot.addGraph(new JKQTPGeoLine(&plot, 1, 0.05, 1.9, 0.9, QColor("red"), 2));
// a one-sided infinite line with slope dy/dx=0.25/0.2
JKQTPGeoInfiniteLine* infLine=new JKQTPGeoInfiniteLine(&plot, 1.7, 0.2, 0.2, 0.25, QColor("green"), 1.5, Qt::PenStyle::DashLine);
infLine->setTwoSided(false);
infLine->setAlpha(0.5);
plot.addGraph(infLine);
// a polyline
QVector<QPointF> p;
p<<QPointF(1, 0.1)<<QPointF(1.3, 0.9)<<QPointF(1.6, 0.3)<<QPointF(1.9, 0.8);
plot.addGraph(new JKQTPGeoPolyLines(&plot, p, QColor("darkgreen"), 4, Qt::PenStyle::DashDotLine));
// rectangle:
plot.addGraph(new JKQTPGeoRectangle(&plot, QPointF(0.4,1.3), QPointF(0.9,1.6), QColor("blue"), 1, Qt::SolidLine, rfill));
// a rotated rectangle (rotated by 35 degrees):
plot.addGraph(new JKQTPGeoRectangle(&plot, 0.5,1.5,0.8,0.5, 35, QColor("darkblue"), 2, Qt::DashLine));
// ellipse:
plot.addGraph(new JKQTPGeoEllipse(&plot, QPointF(0.4,1.3), QPointF(0.9,1.6), QColor("blue"), 1, Qt::SolidLine, rfill));
// a rotated ellipse (rotated by 35 degrees):
plot.addGraph(new JKQTPGeoEllipse(&plot, 0.5,1.5,0.8,0.5, 35, QColor("darkblue"), 2, Qt::DashLine));
// a polygon
JKQTPGeoPolygon* polygraph=new JKQTPGeoPolygon(&plot, QColor("red"), 2, Qt::PenStyle::DashLine, QColor("salmon"));
polygraph->appendPoint(2.1, 0.5);
polygraph->appendPoint(2.9, 0.9);
polygraph->appendPoint(2.2, 0.8);
polygraph->appendPoint(2.8, 0.25);
polygraph->appendPoint(2.6, 0.6);
polygraph->setAlpha(0.75);
plot.addGraph(polygraph);
// an arc from an ellipse from -10 degrees to 117 degrees, centered at 2.5,1.5 and full axes of 0.5 and 0.5
plot.addGraph(new JKQTPGeoArc(&plot,2.5,1.5,0.5,0.5, -10, 117 , QColor("orange"), 4, Qt::PenStyle::DashLine));
// a pie centered at 2.5,2.5 with ellipse axes 0.9 and 0.9 and from angle 0 degrees to 90 degrees
plot.addGraph(new JKQTPGeoPie(&plot,2.5,2.5,0.9,0.9, 0, 90 , QColor("blue"), 4, Qt::PenStyle::SolidLine,QColor("lightblue")));
// a chord centered at 2.5,2.5 with ellipse axes 0.9 and 0.9 and from angle 0 degrees to 90 degrees
plot.addGraph(new JKQTPGeoChord(&plot,2.5,2.5,0.9,0.9, 0, 90 , QColor("blue"), 4, Qt::PenStyle::SolidLine,QColor("lightblue")));
The result of the example combines all these elements and looks like this: