FHWS/Fusion2016
Archived
3
0
Fork 0
Code Issues 1 Pull Requests Releases Wiki Activity
This repository has been archived on 2020-04-08. You can view files and clone it, but cannot push or open issues or pull requests.
Files
41713a5d47959a3a90c2cd63faf4f8fc5e8a473b
Fusion2016/code/eval/EvalBase.h

263 lines
6.2 KiB
C++
Raw Blame History

#ifndef EVALBASE_H
#define EVALBASE_H
#include "../Settings.h"
#include "../Helper.h"
#include "../Vis.h"
#include <KLib/math/filter/particles/ParticleFilter.h>
#include <KLib/math/statistics/Statistics.h>
#include "GroundTruthWay.h"
#include "../particles/P3.h"
#include "../particles/MyState.h"
#include "../particles/MyObservation.h"
#include "../particles/MyEvaluation.h"
#include "../particles/MyTransition.h"
#include "../particles/MyInitializer.h"
#include "../reader/SensorReader.h"
#include "../reader/SensorReaderStep.h"
#include "../reader/SensorReaderTurn.h"
#include "../lukas/TurnObservation.h"
#include "../lukas/StepObservation.h"
#include "../toni/BarometerSensorReader.h"
#include "../frank/WiFiSensorReader.h"
#include "../frank/BeaconSensorReader.h"
class EvalBase {
protected:
Grid<MyGridNode> grid;
Helper::FHWSFloors floors;
Vis vis;
K::ParticleFilter<MyState, MyControl, MyObservation>* pf;
SensorReader* sr;
SensorReaderTurn* srt;
SensorReaderStep* srs;
GroundTruthWay gtw;
std::string runName;
public:
EvalBase() : grid(MiscSettings::gridSize_cm), floors(Helper::getFloors()) {
// build the grid
Helper::buildTheGrid(grid, floors);
// setup the visualisation
vis.addFloor(floors.f0, floors.h0);
vis.addFloor(floors.f1, floors.h1);
vis.addFloor(floors.f2, floors.h2);
vis.addFloor(floors.f3, floors.h3);
}
void run() {
// read CSV input
// const int s_wifi = 0;
//SensorReader sr("/apps/workspaces/ipin2015/measurements/2/1427362412784.csv");
const int s_wifi = 8; const int s_beacons = 9; const int s_barometer = 5;
const int s_linearAcceleration = 2;
std::list<TurnObservation> turn_observations;
std::list<StepObservation> step_observations;
//Create an BarometerSensorReader
BarometerSensorReader baroSensorReader;
//Read all turn Observations
while(srt->hasNext()) {
SensorEntryTurn set = srt->getNext();
TurnObservation to;
to.ts = set.ts;
to.delta_heading = set.delta_heading;
to.delta_motion = set.delta_motion;
turn_observations.push_back(to);
}
//Step Observations
while(srs->hasNext()) {
SensorEntryStep ses = srs->getNext();
StepObservation so;
so.ts = ses.ts;
step_observations.push_back(so);
}
// the to-be-evaluated observation
MyObservation obs;
std::vector<Point3> pathEst;
uint64_t lastTransitionTS = 0;
bool firstReading = true;
int64_t start_time = -1;
K::Statistics<double> stats;
// process each sensor reading
while(sr->hasNext()) {
// get the next sensor reading from the CSV
const SensorEntry se = sr->getNext();
//start_time needed for time calculation of steps and turns
obs.latestSensorDataTS = se.ts;
if (start_time == -1) {start_time = se.ts;}
int64_t current_time = se.ts - start_time;
// ensure the graph timestamp starts with the first reading
if (firstReading) {
//vis.debugProcess(se.ts, pathEst, gtw, pf, layers);
firstReading = false;
}
switch(se.idx) {
case s_wifi: {
obs.wifi = WiFiSensorReader::readWifi(se);
break;
}
case s_beacons: {
BeaconObservationEntry boe = BeaconSensorReader::getBeacon(se);
if (!boe.mac.empty()) {
obs.beacons.entries.push_back(boe);
} // add the observed beacon
obs.beacons.removeOld(obs.latestSensorDataTS);
break;
}
case s_barometer: {
obs.barometer = baroSensorReader.readBarometer(se);
break;
}
case s_linearAcceleration:{
baroSensorReader.readVerticalAcceleration(se);
break;
}
}
// scheduled transition every 500 ms
if (lastTransitionTS == 0) {lastTransitionTS = se.ts;}
for ( ; se.ts - lastTransitionTS > MiscSettings::timeSteps; lastTransitionTS += MiscSettings::timeSteps) {
//Steps are sorted in the list by timestamp.
//If the current observation timestamp is bigger/equal
//to the current step timestamp, use this step as observation
//and remove it from the list.
//The new first timestamp in the list will be then be the next one (timestamp-wise)
StepObservation so;
if(current_time >= step_observations.front().ts && !step_observations.empty()) {
so.step = true;
so.ts = current_time;
obs.step = &so;
step_observations.pop_front();
}
else {
so.step = false;
so.ts = current_time;
obs.step = &so;
}
TurnObservation to;
//same principal as for steps is applied for turns
if(current_time >= turn_observations.front().ts && !turn_observations.empty()) {
to = turn_observations.front();
obs.turn = &to;
turn_observations.pop_front();
}
else {
to.delta_heading = 0.0;
to.delta_motion = 0.0;
obs.turn = &to;
}
// let the transition know the current timestamp to determine the time since the last transition
//if (!useSimpleTrans) {
((MyTransition*)pf->getTransition())->setCurrentTime(lastTransitionTS);
//} else {
// ((MyTransitionSimple*)pf->getTransition())->setCurrentTime(lastTransitionTS);
//}
// update the particle filter (transition + eval), estimate a new current position and add it to the estimated path
const MyState est = pf->update(nullptr, obs);
const Point3 curEst = est.pCur;
pathEst.push_back(curEst);
// debug print current particle set.
//vis.debugProcess(se.ts, pathEst, gtw, pf, layers);
// error calculation. compare ground-truth to estimation
// const Point3 curGT = gtw.getPosAtTime(se.ts - 750);
// // TODO
// const Point3 diff = curEst - curGT;
// //if (std::abs(diff.z) < 0.1) {
// const float err = diff.length();
// std::cout << err << std::endl;
// stats.add(err);
// std::cout << stats.asString() << std::endl;
// //}
vis.clearStates();
for (const K::Particle<MyState> p : pf->getParticles()) {vis.addState(p.state.walkState);}
vis.show();;
}
}
{
// vis.setShowParticles(false);
// vis.setShowTime(false);
// vis.setShowCurPos(false);
// vis.debugProcess(0, pathEst, gtw, pf, layers);
// std::ofstream out("/tmp/" + runName + ".data");
// out << vis.getDataset();
// out.close();
}
sleep(1000);
}
};
#endif // EVALBASE_H
Reference in New Issue View Git Blame Copy Permalink