bool StudentLocalization::stepFindChinContours(const IntensityImage &image, FeatureMap &features) const {
const Feature & mouthCenter = features.getFeature(Feature::FEATURE_MOUTH_CENTER);
const Feature & chin = features.getFeature(Feature::FEATURE_CHIN);
Feature & chinContour = features.getFeature(Feature::FEATURE_CHIN_CONTOUR);
// The mouth could interfere with the localization of the chin contours.
// Therefore use an offset based on which mouthcorner is the furthest away.
// This however could still prove troublesome, so add a slight margin;
// represented by the 'magic' number.
const double radius = chin.getY() - mouthCenter.getY();
const double smallestOffsetRadiusFactor = 0.75;
const double biggestOffsetRadiusFactor = 2;
//
// 180° matches half a circle.
// 0° points to the east in goniometrics, where increasing angles are counter-clockwise.
// Since the chin is usually on the bottompart of the image, the points either need to be
// found clockwise (-180), or start looking at an offset.
//
const int halfCircle = 180;
const int angleStepSize = 10;
// roughly 19 points need to be found.
// 0 through 18 does just that.
for (int i = 0; i <= halfCircle / angleStepSize; ++i)
{
// Determine the angle of the line among which we try to look for a point on the chin's contour.
int angle = halfCircle + i * angleStepSize;
// The size of a step in both the horizontal and verticical direction along the line with the current angle.
double xDir = std::cos(angle * M_PI / 180.0);
double yDir = -std::sin(angle * M_PI / 180.0);
// Normalized size of a step that is made alongside the current angle.
const double increment = 1;
// Make multiple steps alongside the current angle within bounds where it is likely a contour for the chin.
for (double distance = radius * smallestOffsetRadiusFactor; distance < radius * biggestOffsetRadiusFactor; distance += increment)
{
// Determine the location to check for a contour of the chin.
double xCheck = mouthCenter.getX() + (xDir * distance);
double yCheck = mouthCenter.getY() + (yDir * distance);
// Image should be thresholded grayscale, where the pixels are eiher 0 or 255; check in the middle of it.
const unsigned char treshhold = 128;
if (image.getPixel(xCheck, yCheck) <= treshhold)
{
chinContour.addPoint(Point2D<double>(xCheck, yCheck));
std::cout << "Found contour at: " << xCheck << "; " << yCheck << "\n";
break;
}
}
}
return (chinContour.getPoints().size() > 0);
}
IntensityImageStudent::IntensityImageStudent(const IntensityImage &other) : IntensityImage(other.getWidth(), other.getHeight()), pixelMap(nullptr) {
const int SIZE = other.getSize();
if(SIZE > 0) {
pixelMap = new Intensity[SIZE];
for(int i = 0; i < SIZE; i++) {
pixelMap[i] = other.getPixel(i);
}
}
}
int StudentLocalization::getTopOfHead(const IntensityImage &image){
for (int y = 0; y < image.getHeight(); y++){
for (int x = 0; x < image.getWidth(); x++) {
if (image.getPixel(x, y) == 0){
return y;
}
}
}
return -1;
}
void HereBeDragons::HerLoveForWhoseDearLoveIRiseAndFall(const IntensityImage &src, cv::Mat &dst) {
int w = src.getWidth();
int h = src.getHeight();
dst.create(h, w, CV_8UC1);
for (int x = 0; x < dst.cols; x++) {
for (int y = 0; y < dst.rows; y++) {
dst.at<uchar>(y, x) = src.getPixel(x, y);
}
}
}
void IntensityImageStudent::set(const IntensityImage &other) {
const int SIZE = other.getSize();
IntensityImage::set(other.getWidth(), other.getHeight());
if (SIZE > 0) {
delete[] pixelMap;
pixelMap = new Intensity[SIZE];
for (int i = 0; i < SIZE; i++) {
pixelMap[i] = other.getPixel(i);
}
}
}
SonnetXVIII HereBeDragons::YetWhoKnowsNotConscienceIsBornOfLove(const IntensityImage &Yet, const int Who, const int Knows, const int Not, const int Conscience){
SonnetXVIII Is(Conscience);
int Born = 0;
for (int y = Knows; y < (Knows + Conscience); y++){
for (int x = Who; x < (Who + Not); x++){
if (Yet.getPixel(x, y) == 0){
Is[Born]++;
}
}
Born++;
}
return Is;
}
SonnetXVIII HereBeDragons::LoveIsTooYoungToKnowWhatConscienceIs(const IntensityImage &Love, const int Is, const int Too, const int Young, const int To){
SonnetXVIII Know(Young);
int What = 0;
for (int x = Is; x < (Is + Young); x++){
for (int y = Too; y < (Too + To); y++){
if (Love.getPixel(x, y) == 0){
Know[What]++;
}
}
What++;
}
return Know;
}
IntensityImageStudent GaussianFilter::applyFilter(const IntensityImage &image)
{
IntensityImageStudent filteredImage = IntensityImageStudent(image.getWidth() - 2 * radius, image.getHeight() - 2 * radius);
for (int y = 0; y < filteredImage.getHeight(); y++){
for (int x = 0; x < filteredImage.getWidth(); x++){
double filteredIntensity = 0.0;
for (unsigned int i = 0; i < gaussKernel.size(); i++){
filteredIntensity += gaussKernel[i] * image.getPixel(x + (i % (2 * radius + 1)), y + i / (2 * radius + 1));
}
filteredImage.setPixel(x, y, static_cast<Intensity>(filteredIntensity));
}
}
return filteredImage;
}
bool StudentLocalization::stepFindChinContours(const IntensityImage &image, FeatureMap &features) const {
//Get the position of the mouth
Feature Mouth = features.getFeature(Feature::FEATURE_MOUTH_TOP);
Point2D<double> MouthPosition;
//Initialise the chin feature
std::vector<Point2D<double>> ChinPositions;
Feature Chin = Feature(Feature::FEATURE_CHIN);
Feature ChinContour = Feature(Feature::FEATURE_CHIN_CONTOUR);
int y = 0;
int m = 0;
//Draw a half circle starting from the center of the mouth
for (int j = HALF_CIRCLE; j > 0; j -= DEGREE_STEP){
//reset the position of the mouth
MouthPosition.set(Mouth.getX(), Mouth.getY());
MouthPosition.set(drawLine(j, START_POSITION, MouthPosition));
m = m + 1;
for (int i = 0; i < MEASURE_RANGE; i++){
MouthPosition.set(drawLine(j, MEASURE_STEP, MouthPosition));
Intensity pixel = image.getPixel(MouthPosition.getX(), MouthPosition.getY());
// If the intensity of the current pixel is lower than 2 (which means it is black)
if (pixel < 2){
// If the current angle is within the bounds of the half circle
if (j < RIGHT_HALF && j > LEFT_HALF){
ChinContour.addPoint(drawLine(j, 2, MouthPosition));
}
else{
//Draw a point on the mouth position, to indicate the detection failed.
ChinContour.addPoint(MouthPosition);
}
break;
}
}
}
features.putFeature(ChinContour);
return true;
}
bool StudentLocalization::stepFindChinContours(const IntensityImage &image, FeatureMap &features) const {
// Maak een basetimer object om de tijd bij te houden dat de implementatie nodig heeft.
BaseTimer basetimer;
// Start de basetimer.
basetimer.start();
// test getal
int startStep = 15;
bool first = true;
// Sla het middenpunt van de mond op.
Point2D<double> MouthCenterPoint = features.getFeature(Feature::FEATURE_MOUTH_CENTER).getPoints()[0];
// Sla het kin punt op.
Point2D<double> ChinPoint = features.getFeature(Feature::FEATURE_CHIN).getPoints()[0];
int range = MouthCenterPoint.getY() - ChinPoint.getY();
// Object om kincountoer punten in op te slaan.
Feature output = Feature(Feature::FEATURE_CHIN_CONTOUR);
int degrees;
int steps = 15;
int lastdif;
double correction = -1;
int lastSteps = 0;
int vorigeX = 0;
// Bereken 20 punten van de kin.
for (int i = 0; i < 19; i++)
{
bool ireg = false;
if (i>9)
{
correction = 1;
}
else if (i < 9)
{
correction =0;
}
// Sla middelpunt mond x op.
int checkX = MouthCenterPoint.getX();
// Sla middelpunt mond y op.
int checkY = MouthCenterPoint.getY();
double gradenInRad = (-90+(i * 10)) *(PI/180);
steps = startStep;
Point2D<double> gevondenPunt;
// Middelste punt van de kin is als het goed is bekend. Dit is punt nummer 9 dus zal worden overgeslagen.
if (i != 9)
{
while (true)
{
if (!first&&steps > startStep + 10)
{
lastdif / i;
ireg = true;
gevondenPunt.set(MouthCenterPoint.getX() + ((lastSteps + correction)* std::sin(gradenInRad)), MouthCenterPoint.getY() + ((lastSteps + correction) * std::cos(gradenInRad)));
steps = lastSteps + correction;
break;
}
checkX = MouthCenterPoint.getX()+ (steps * std::sin(gradenInRad));
checkY = MouthCenterPoint.getY()+(steps * std::cos(gradenInRad));
Intensity pixel = image.getPixel(std::round(checkX), std::round(checkY));
if (int(pixel) == 0)
{
if (checkX - vorigeX <2)
{
lastdif / i;
ireg = true;
gevondenPunt.set(MouthCenterPoint.getX() + ((lastSteps + correction)* std::sin(gradenInRad)), MouthCenterPoint.getY() + ((lastSteps + correction) * std::cos(gradenInRad)));
steps = lastSteps + correction;
break;
}
ireg=false;
gevondenPunt.set(checkX, checkY); break;
}
steps++;
}
vorigeX = checkX;
std::cout << gevondenPunt <<"\n";
startStep = steps - 5;
output.addPoint(Point2D<double>(gevondenPunt.x,gevondenPunt.y));
first=false;
if (ireg)
{
startStep = steps-5;
lastSteps = steps;
}
else
{
lastdif = lastSteps - steps;
lastSteps = steps;
}
}
else
{
output.addPoint(ChinPoint);
}
}
features.putFeature(output);
basetimer.stop();
std::ofstream myfile;
myfile.open("tijd.txt", std::ofstream::ate);
myfile << "Chincontours convert tijd in s: " << basetimer.elapsedSeconds() << " tijd ms:" << basetimer.elapsedMilliSeconds() << " tijd us" << basetimer.elapsedMicroSeconds();
myfile.close();
return true;
}