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#include "MovingPointTracker.h"
MovingPointTracker::MovingPointTracker() {
active_objects = 0;
nextID = 0;
}
MovingPointTracker::~MovingPointTracker() {
}
float MovingPointTracker::pointDistance(cv::Point2f &pt1, cv::Point2f &pt2) {
cv::Point2f diff = pt1 - pt2;
return cv::sqrt(diff.x * diff.x + diff.y * diff.y);
}
std::vector<MOVING_OBJECT> MovingPointTracker::update(std::vector<cv::Point2f> points) {
// Mark each existing object as invalid
for (int i = 0; i < objects.size(); i++) {
objects[i].valid = false;
}
std::vector<MOVING_OBJECT> newObjects;
// For each point, determine if it is an extension of an existing object
for (int i = 0; i < points.size(); i++) {
bool found = false;
int index;
for (index = 0; index < objects.size(); index++) {
// Find the first object within the distance threshold
// TODO: calculate all distances and use the closest one
// TODO: handle case where multiple objects are merged into one
if (pointDistance(points[i], objects[index].last_known_pt) < OBJECT_DISTANCE_THRESHOLD) {
found = true;
break;
}
}
if (found) {
// If a match was found, update the object
objects[index].valid = true;
// Predict the next point using the Kalman filter
objects[index].filter->predict();
objects[index].last_known_pt = points[i];
objects[index].predicted_pt = objects[index].filter->correct(points[i].x, points[i].y);
// Calculate the running average
objects[index].history.push_front(objects[index].predicted_pt);
if (objects[index].history.size() > HISTORY_DEPTH)
objects[index].history.pop_back();
float avgX = 0, avgY = 0;
for (std::list<cv::Point2f>::iterator it = objects[index].history.begin(); it != objects[index].history.end(); it++) {
avgX += (*it).x;
avgY += (*it).y;
}
avgX /= objects[index].history.size();
avgY /= objects[index].history.size();
objects[index].historyAvg = cv::Point2f(avgX, avgY);
// Calculate the updated velocity and angle
objects[index].velocity = pointDistance(objects[index].predicted_pt, objects[index].historyAvg);
cv::Point2f diff = objects[index].predicted_pt - objects[index].historyAvg;
objects[index].angle = atan2(diff.y, diff.x);
} else {
// If no matches were found, create a new object
MOVING_OBJECT newObject;
newObject.ID = nextID;
nextID++;
newObject.last_known_pt = points[i];
newObject.predicted_pt = points[i];
newObject.velocity = 0;
newObject.angle = 0;
newObject.filter = new KalmanFilter(points[i].x, points[i].y);
newObject.historyAvg = cv::Point2f(0, 0);
newObjects.push_back(newObject);
}
}
// If an object is invalid at this point, remove it
//std::vector<MOVING_OBJECT> newObjects;
for (int i = 0; i < objects.size(); i++) {
if (objects[i].valid) {
newObjects.push_back(objects[i]);
}
}
objects = newObjects;
return objects;
}