mirror of
https://github.com/jkriege2/JKQtPlotter.git
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f2004a6f66
IMPROVED/REWORKED: legend/key positioning as combination of 3 values, e.g. \c JKQTPKeyOutsideTop|JKQTPKeyTop|JKQTPKeyRight or \c JKQTPKeyInside|JKQTPKeyTopJKQTPKeyRight
277 lines
16 KiB
C++
277 lines
16 KiB
C++
/** \example datastore_groupedstat.cpp
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* Explains how to use the internal statistics library (see \ref jkqtptools_statistics ) together with JKQTPDatastore to generate grouped statistics (i.e. calculates errorbars or boxplots from groups of datapoints in a x/y-dataset).
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*
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* \ref JKQTPlotterBasicJKQTPDatastoreStatisticsGroupedStat
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*/
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#include "jkqtpexampleapplication.h"
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#include <QApplication>
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#include "jkqtplotter/jkqtplotter.h"
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#include "jkqtplotter/graphs/jkqtpscatter.h"
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#include "jkqtplotter/graphs/jkqtpbarchart.h"
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#include "jkqtplotter/graphs/jkqtpstatisticsadaptors.h"
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#include "jkqtmath/jkqtpstatisticstools.h"
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#include "jkqtcommon/jkqtpstringtools.h"
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#include <random>
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#include <cmath>
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#include <vector>
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int main(int argc, char* argv[])
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{
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JKQTPAppSettingController highDPIController(argc, argv);
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JKQTPExampleApplication app(argc, argv);
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// 1. create a window with several plotters and get a pointer to the internal datastores (for convenience)
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QWidget mainWidget;
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QGridLayout* lay;
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mainWidget.setLayout(lay=new QGridLayout);
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JKQTPlotter* plotbarchart=new JKQTPlotter(&mainWidget);
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plotbarchart->getPlotter()->setPlotLabel("Barcharts");
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JKQTPDatastore* datastore1=plotbarchart->getDatastore();
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lay->addWidget(plotbarchart,0,0);
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JKQTPlotter* plotboxplot=new JKQTPlotter(datastore1, &mainWidget);
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plotboxplot->getPlotter()->setPlotLabel("Boxplots");
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lay->addWidget(plotboxplot,0,1);
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JKQTPlotter* plotscattererrors=new JKQTPlotter(datastore1, &mainWidget);
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plotscattererrors->getPlotter()->setPlotLabel("Scatter Plot with Error Indicators");
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lay->addWidget(plotscattererrors,0,2);
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lay->setColumnStretch(0,1);
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lay->setColumnStretch(1,1);
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lay->setColumnStretch(2,2);
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// 2. Barcharts from categorized data:
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// 2.1. First we generate a dataset, which is going to be used for a barchart
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// The datapoints consist of pairs <group,value>, where the groups are encoded
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// by the numbers 1,2,3 and in each group, several measurements are taken
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size_t colBarRawGroup=datastore1->addColumn("barchart, rawdata, group");
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size_t colBarRawValue=datastore1->addColumn("barchart, rawdata, value");
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// data for group 1
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.1);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.5);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 0.8);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.2);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.4);
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// data for group 2
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.2);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.4);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 1.9);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.6);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.1);
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// data for group 3
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.1);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.4);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 3.8);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.5);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 3.7);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.0);
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// now some more datapoint, in mixed order
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 0.9);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.3);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.0);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.0);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.2);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.25);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.35);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 3.7);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 0.75);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 1.85);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.5);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 0.95);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 1.65);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 3, 4.1);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 1, 1.15);
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datastore1->appendToColumns(colBarRawGroup, colBarRawValue, 2, 2.15);
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// 2.2. This dataset can be visualized with a simple scatter plot:
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JKQTPXYLineGraph* gScatterForBar;
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plotbarchart->addGraph(gScatterForBar=new JKQTPXYLineGraph(plotbarchart));
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gScatterForBar->setXYColumns(colBarRawGroup, colBarRawValue);
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gScatterForBar->setDrawLine(false);
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gScatterForBar->setSymbolType(JKQTPCross);
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gScatterForBar->setSymbolSize(5);
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gScatterForBar->setSymbolColor(QColorWithAlphaF(QColor("red"), 0.5));
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// 2.3. Now we want to draw a barchart for every group, which indicates the
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// average in each group. This is done using methods from the statistics
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// library.
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// First we need to group the data using jkqtpstatGroupData(), which assembles
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// the data points in each group groupeddataBar
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std::map<double, std::vector<double> > groupeddataBar;
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jkqtpstatGroupData(datastore1->begin(colBarRawGroup), datastore1->end(colBarRawGroup),
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datastore1->begin(colBarRawValue), datastore1->end(colBarRawValue),
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groupeddataBar);
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// now we can calculate the statistics for each group separately:
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// Data is collected in two new columns
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size_t colBarGroup=datastore1->addColumn("barchart, group");
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size_t colBarAverage=datastore1->addColumn("barchart, group-average");
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size_t colBarStdDev=datastore1->addColumn("barchart, group-stddev");
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// Statistics is calculated by simply iterating over groupeddataBar
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// and calling functions like jkqtpstatAverage() for each group
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for (auto it=groupeddataBar.begin(); it!=groupeddataBar.end(); ++it) {
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datastore1->appendToColumn(colBarGroup, it->first);
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datastore1->appendToColumn(colBarAverage, jkqtpstatAverage(it->second.begin(), it->second.end()));
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datastore1->appendToColumn(colBarStdDev, jkqtpstatStdDev(it->second.begin(), it->second.end()));
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}
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// 2.4. Finally the calculated groups are drawn
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JKQTPBarVerticalErrorGraph* gBar;
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plotbarchart->addGraph(gBar=new JKQTPBarVerticalErrorGraph(plotbarchart));
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gBar->setXYColumns(colBarGroup, colBarAverage);
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gBar->setYErrorColumn(static_cast<int>(colBarStdDev));
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// 2.5. With the methods above we can also calculate more advanced statistics, like e.g. boxplots:
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size_t colBarMedian=datastore1->addColumn("barchart, group-median");
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size_t colBarMin=datastore1->addColumn("barchart, group-min");
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size_t colBarMax=datastore1->addColumn("barchart, group-max");
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size_t colBarQ25=datastore1->addColumn("barchart, group-Q25");
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size_t colBarQ75=datastore1->addColumn("barchart, group-Q75");
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for (auto it=groupeddataBar.begin(); it!=groupeddataBar.end(); ++it) {
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datastore1->appendToColumn(colBarMedian, jkqtpstatMedian(it->second.begin(), it->second.end()));
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datastore1->appendToColumn(colBarMin, jkqtpstatMinimum(it->second.begin(), it->second.end()));
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datastore1->appendToColumn(colBarMax, jkqtpstatMaximum(it->second.begin(), it->second.end()));
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datastore1->appendToColumn(colBarQ25, jkqtpstatQuantile(it->second.begin(), it->second.end(), 0.25));
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datastore1->appendToColumn(colBarQ75, jkqtpstatQuantile(it->second.begin(), it->second.end(), 0.75));
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}
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// 2.6. The result can be plotted using JKQTPBoxplotVerticalGraph, which receives a column for each value class of the final plot:
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JKQTPBoxplotVerticalGraph* gBoxplot;
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plotboxplot->addGraph(gBoxplot=new JKQTPBoxplotVerticalGraph(plotboxplot));
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gBoxplot->setPositionColumn(colBarGroup);
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gBoxplot->setMinColumn(colBarMin);
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gBoxplot->setMaxColumn(colBarMax);
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gBoxplot->setMedianColumn(colBarMedian);
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gBoxplot->setPercentile25Column(colBarQ25);
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gBoxplot->setPercentile75Column(colBarQ75);
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// 2.7. In order to safe yo the typing of the code above, shortcuts in the form of adaptors exist:
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/*
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jkqtpstatAddYErrorBarGraph(plotbarchart->getPlotter(),
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datastore1->begin(colBarRawGroup), datastore1->end(colBarRawGroup),
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datastore1->begin(colBarRawValue), datastore1->end(colBarRawValue));
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jkqtpstatAddHBoxplotsAndOutliers(plotboxplot->getPlotter(),
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datastore1->begin(colBarRawGroup), datastore1->end(colBarRawGroup),
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datastore1->begin(colBarRawValue), datastore1->end(colBarRawValue));
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*/
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// 3. Scatterplots from categorized data:
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// 3.1. First we generate a second dataset, which is going to be used for a scaterplot
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// The datapoints consist of pairs <x,y>, that are based on a parabula with random
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// deviations, both in x- and y-direction
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size_t colScatterRawX=datastore1->addColumn("scatterplot, rawdata, x");
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size_t colScatterRawY=datastore1->addColumn("scatterplot, rawdata, y");
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std::random_device rd; // random number generators:
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std::mt19937 gen{rd()};
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gen.seed(12345);
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std::normal_distribution<> d1{0,0.5};
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const size_t N=100;
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const double xmax=3.5;
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for (size_t i=0; i<N; i++) {
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const double x=(static_cast<double>(i)-static_cast<double>(N)/2.0)*xmax/(static_cast<double>(N)/2.0);
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const double y=jkqtp_sqr(x)+2.0;
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datastore1->appendToColumns(colScatterRawX, colScatterRawY, x+d1(gen), y+d1(gen));
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}
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// 3.2. Now we can also add the raw dataset to the plot for visualization:
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JKQTPXYParametrizedScatterGraph* gScatterRaw;
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plotscattererrors->addGraph(gScatterRaw=new JKQTPXYParametrizedScatterGraph(plotscattererrors));
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gScatterRaw->setXYColumns(colScatterRawX, colScatterRawY);
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gScatterRaw->setDrawLine(false);
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gScatterRaw->setSymbolType(JKQTPCross);
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gScatterRaw->setSymbolSize(5);
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// 3.3. Now we want to draw a scatterchart of the data, where data-points should be grouped
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// together, in x-intervals of width 0.5. From all the points in each interval, we calculate the
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// in both x- and y-direction the average and standard deviation.
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// First we need to group the data using jkqtpstatGroupData(), which assembles
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// the data points in each group groupeddataScatter. For the custom grouping of the datapoints
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// we use the optional functor provided to jkqtpstatGroupData(): We use jkqtpstatGroupingCustomRound1D()
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// with given parameters 0.25 for the (center) location of the first bin and bin width 0.5. The functor
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// is not built by hand (which would be possible using std::bind), but with the generator function
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// jkqtpstatMakeGroupingCustomRound1D().
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// in addition we use a variant of jkqtpstatGroupData(), which outputs a column with the category
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// assigned to every data pair in the input data range
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std::map<double, std::pair<std::vector<double>,std::vector<double> > > groupeddataScatter;
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size_t colScatterRawGroup=datastore1->addColumn("scatterplot, rawdata, assigned-group");
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jkqtpstatGroupData(datastore1->begin(colScatterRawX), datastore1->end(colScatterRawX),
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datastore1->begin(colScatterRawY), datastore1->end(colScatterRawY),
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datastore1->backInserter(colScatterRawGroup),
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groupeddataScatter,
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jkqtpstatMakeGroupingCustomRound1D(0.25, 0.5));
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// The column colScatterRawGroup can now be used to color the scatter graph:
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gScatterRaw->setColorColumn(colScatterRawGroup);
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// now we can calculate the statistics for each group separately:
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// Data is collected in two new columns
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size_t colScatterXAvg=datastore1->addColumn("scatter, x, average");
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size_t colScatterXStd=datastore1->addColumn("scatter, x, stddev");
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size_t colScatterYAvg=datastore1->addColumn("scatter, y, average");
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size_t colScatterYStd=datastore1->addColumn("scatter, y, stddev");
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// Statistics is calculated by simply iterating over groupeddataScatter
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// and calling functions like jkqtpstatAverage() for each group
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for (auto it=groupeddataScatter.begin(); it!=groupeddataScatter.end(); ++it) {
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datastore1->appendToColumn(colScatterXAvg, jkqtpstatAverage(it->second.first.begin(), it->second.first.end()));
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datastore1->appendToColumn(colScatterXStd, jkqtpstatStdDev(it->second.first.begin(), it->second.first.end()));
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datastore1->appendToColumn(colScatterYAvg, jkqtpstatAverage(it->second.second.begin(), it->second.second.end()));
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datastore1->appendToColumn(colScatterYStd, jkqtpstatStdDev(it->second.second.begin(), it->second.second.end()));
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}
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// 3.4. Finally the calculated groups are drawn
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JKQTPXYLineErrorGraph* gScatterErr;
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plotscattererrors->addGraph(gScatterErr=new JKQTPXYLineErrorGraph(plotscattererrors));
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gScatterErr->setXYColumns(colScatterXAvg, colScatterYAvg);
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gScatterErr->setXErrorColumn(static_cast<int>(colScatterXStd));
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gScatterErr->setYErrorColumn(static_cast<int>(colScatterYStd));
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gScatterErr->setSymbolType(JKQTPFilledTriangle);
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gScatterErr->setDrawLine(false);
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// 3.5. also here an adaptor exists, which makes the task easier:
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/*
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jkqtpstatAddXYErrorLineGraph(plotscattererrors->getPlotter(),
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datastore1->begin(colScatterRawX), datastore1->end(colScatterRawX),
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datastore1->begin(colScatterRawY), datastore1->end(colScatterRawY),
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jkqtpstatMakeGroupingCustomRound1D(0.25, 0.5));
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*/
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// autoscale the plot so the graph is contained
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plotboxplot->synchronizeToMaster(plotbarchart, JKQTBasePlotter::sdXYAxes);
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plotboxplot->zoomToFit();
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plotboxplot->setGrid(false);
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plotboxplot->setShowZeroAxes(false);
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plotboxplot->getMainKey()->setBackgroundBrush(QBrush(QColorWithAlphaF("white", 0.25), Qt::SolidPattern));
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plotbarchart->setAbsoluteY(0,5);
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plotboxplot->setAbsoluteY(0,5);
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plotbarchart->zoomToFit();
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plotbarchart->setGrid(false);
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plotbarchart->setShowZeroAxes(false);
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plotbarchart->getMainKey()->setBackgroundBrush(QBrush(QColorWithAlphaF("white", 0.25), Qt::SolidPattern));
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plotbarchart->moveGraphTop(gScatterForBar);
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plotscattererrors->zoomToFit();
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plotscattererrors->setGrid(false);
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plotscattererrors->setShowZeroAxes(false);
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plotscattererrors->getMainKey()->setBackgroundBrush(QBrush(QColorWithAlphaF("white", 0.25), Qt::SolidPattern));
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// show plotter and make it a decent size
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mainWidget.show();
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mainWidget.resize(900,300);
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app.addExportStepPlotFunctor([&]() { gBar->setVisible(false); plotbarchart->redrawPlot(); return plotbarchart;});
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app.addExportStepPlotFunctor([&]() { gBar->setVisible(true); plotbarchart->redrawPlot(); return plotbarchart;});
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app.addExportStepPlotFunctor([&]() { return plotboxplot; });
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app.addExportStepPlotFunctor([&]() { gScatterErr->setVisible(false); plotscattererrors->redrawPlot(); return plotscattererrors;});
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app.addExportStepPlotFunctor([&]() { gScatterErr->setVisible(true); plotscattererrors->redrawPlot(); return plotscattererrors;});
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return app.exec();
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}
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