TP-modelisation-images/super_pixel.asv

function germes = super_pixel(img, K, m, n, q_max)
    img = im2double(img);
    img = img(1:10, 1:10, :);

    width = size(img, 1);
    height = size(img, 2);
    N = width * height;

    S = sqrt(N / K);
    X = S / 2:S:width;
    Y = S / 2:S:height;
    germes = zeros(length(X) * length(Y), 5);
    c = 1;

    for x = X

        for y = Y
            germes(c, :) = [x y 0 0 0];
            c = c + 1;
        end

    end

    scatter(germes(:, 2), germes(:, 1), 'g.');

    c = 1;

    for germe = germes'

        x = germe(1);
        y = germe(2);

        xmin = floor(max(x - n, 1));
        interval_x = xmin:min(x + n, width);

        ymin = floor(max(y - n, 1));
        interval_y = ymin:min(y + n, height);
        
        Gmag = imgradient(img(interval_x, interval_y));
        [~, ind_min] = min(Gmag(:));
        [nr, nc] = ind2sub(size(Gmag), ind_min);

        x = xmin + nr - 1;
        y = ymin + nc - 1;

        germes(c, :) = [x y img(x, y, 1) img(x, y, 2) img(x, y, 3)];

        c = c + 1;
    end

    scatter(germes(:, 2), germes(:, 1), 'r.');

    germe_per_pixel = zeros(width, height);

    for q = 1:q_max

        for x = 1:width

            for y = 1:height

                % initialisation des minimums
                min_Ds = +inf;

                index_germe = 0;

                for germe = germes'
                    index_germe = index_germe + 1;

                    % on récupère les coordonnées du germe
                    xg = germe(1);
                    yg = germe(2);

                    % on calcule la distance spatiale entre le germe et le pixel
                    Dxy = norm([x - xg y - yg], 2);

                    % si le germe est trop loin on skip
                    if Dxy > S
                        continue;
                    end

                    % on récupère les couleurs du germe
                    rg = germe(3);
                    gg = germe(4);
                    bg = germe(5);

                    % on récupère les couleurs du pixel
                    r = img(x, y, 1);
                    g = img(x, y, 2);
                    b = img(x, y, 3);

                    % on calcule la distance chromatique entre le germe et le pixel
                    Dlab = norm([r - rg g - gg b - bg], 2);

                    % on calcule Ds
                    Ds = Dlab + m / S * Dxy;

                    % Si Ds est meilleur on le prend
                    if Ds < min_Ds
                        germe_per_pixel(x, y) = index_germe;
                        min_DS = Ds;
                    end

                end

            end

        end

        for index_germe = 1:length(germes)

            truc = germe_per_pixel == index_germe;
            truc_rgb = reshape(img(repmat(truc,[1 1 3])), [], 3);
            mean(truc_rgb);
            mx = 0;
            my = 0;
            

        end

        scatter(germes(:, 2), germes(:, 1), 'b.');

    end

end
feat: ce qui a changé 2022-03-22 07:13:49 +00:00			`function germes = super_pixel(img, K, m, n, q_max)`
			`img = im2double(img);`
			`img = img(1:10, 1:10, :);`

			`width = size(img, 1);`
			`height = size(img, 2);`
			`N = width * height;`

			`S = sqrt(N / K);`
			`X = S / 2:S:width;`
			`Y = S / 2:S:height;`
			`germes = zeros(length(X) * length(Y), 5);`
			`c = 1;`

			`for x = X`

			`for y = Y`
			`germes(c, :) = [x y 0 0 0];`
			`c = c + 1;`
			`end`

			`end`

			`scatter(germes(:, 2), germes(:, 1), 'g.');`

			`c = 1;`

			`for germe = germes'`

			`x = germe(1);`
			`y = germe(2);`

			`xmin = floor(max(x - n, 1));`
			`interval_x = xmin:min(x + n, width);`

			`ymin = floor(max(y - n, 1));`
			`interval_y = ymin:min(y + n, height);`

			`Gmag = imgradient(img(interval_x, interval_y));`
			`[~, ind_min] = min(Gmag(:));`
			`[nr, nc] = ind2sub(size(Gmag), ind_min);`

			`x = xmin + nr - 1;`
			`y = ymin + nc - 1;`

			`germes(c, :) = [x y img(x, y, 1) img(x, y, 2) img(x, y, 3)];`

			`c = c + 1;`
			`end`

			`scatter(germes(:, 2), germes(:, 1), 'r.');`

			`germe_per_pixel = zeros(width, height);`

			`for q = 1:q_max`

			`for x = 1:width`

			`for y = 1:height`

			`% initialisation des minimums`
			`min_Ds = +inf;`

			`index_germe = 0;`

			`for germe = germes'`
			`index_germe = index_germe + 1;`

			`% on récupère les coordonnées du germe`
			`xg = germe(1);`
			`yg = germe(2);`

			`% on calcule la distance spatiale entre le germe et le pixel`
			`Dxy = norm([x - xg y - yg], 2);`

			`% si le germe est trop loin on skip`
			`if Dxy > S`
			`continue;`
			`end`

			`% on récupère les couleurs du germe`
			`rg = germe(3);`
			`gg = germe(4);`
			`bg = germe(5);`

			`% on récupère les couleurs du pixel`
			`r = img(x, y, 1);`
			`g = img(x, y, 2);`
			`b = img(x, y, 3);`

			`% on calcule la distance chromatique entre le germe et le pixel`
			`Dlab = norm([r - rg g - gg b - bg], 2);`

			`% on calcule Ds`
			`Ds = Dlab + m / S * Dxy;`

			`% Si Ds est meilleur on le prend`
			`if Ds < min_Ds`
			`germe_per_pixel(x, y) = index_germe;`
			`min_DS = Ds;`
			`end`

			`end`

			`end`

			`end`

			`for index_germe = 1:length(germes)`

			`truc = germe_per_pixel == index_germe;`
			`truc_rgb = reshape(img(repmat(truc,[1 1 3])), [], 3);`
			`mean(truc_rgb);`
			`mx = 0;`
			`my = 0;`


			`end`

			`scatter(germes(:, 2), germes(:, 1), 'b.');`

			`end`

			`end`