transform_all_rotated90.m 6.2 KB

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clear;

path_name = '/media/rfj/EEA4441FA443E923/nturgb_skeletones/';
fileID = fopen('/home/rfj/바탕화면/actionGAN/skeletone_INDEX/good_stand_2.txt','r');
formatSpec = '%s';
sizeA = [20 Inf];
perfect_list = fscanf(fileID,formatSpec,sizeA);
perfect_list = perfect_list.';
fclose(fileID);

L = length(perfect_list);

for K = 1:L

    file_name = char(perfect_list(K,:));
    name = strcat(path_name,file_name(1:20),'.skeleton');
    [token,remainder] = strtok(file_name,'A');
    class = str2num(remainder(2:4));

    bodyinfo = read_skeleton_file(name);
    frame_num = size(bodyinfo,2);
    try

        %initialize
        cur_subject_x = zeros(frame_num, 25);
        cur_subject_y = zeros(frame_num, 25);
        cur_subject_z = zeros(frame_num, 25);

        tot_x = zeros(frame_num,25);
        tot_y = zeros(frame_num,25);
        tot_z = zeros(frame_num,25);

        joint_5 = zeros(1,3);
        joint_9 = zeros(1,3);
        joint_1 = zeros(1,3);
        joint_3 = zeros(1,3);

        %get total joints information
        for FN = 1:frame_num
            cur_body = bodyinfo(FN).bodies(1);
            joints = cur_body.joints;

            for JN = 1:25
                tot_x(FN,JN) = joints(JN).x;
                tot_y(FN,JN) = joints(JN).y;
                tot_z(FN,JN) = joints(JN).z;
            end
        end

        %Orientation normalization 1 : in space
        %get median values
        M_x = median(tot_x);
        M_y = median(tot_y);
        M_z = median(tot_z);

        %set 3 points for make plane
        joint_5 = [M_x(5) M_y(5) M_z(5)];
        joint_9 = [M_x(9) M_y(9) M_z(9)];
        joint_1 = [M_x(1) M_y(1) M_z(1)];
        joint_3 = [M_x(3) M_y(3) M_z(3)];

        %find RIGID TRNASFORMATION matrix
        d1 = joint_1 - joint_5;
        d2 = joint_1 - joint_9;
        n1 = cross(d1,d2); % because we will parallel transform, don't need to find belly
        u1 = n1/norm(n1);
        u2 = [0 0 1];
        cs1 = dot(u1,u2)/norm(u1)*norm(u2);
        ss1 = sqrt(1-cs1.^2);
        v1 = cross(u1,u2)/norm(cross(u1,u2));

        R1 = [v1(1)*v1(1)*(1-cs1)+cs1 v1(1)*v1(2)*(1-cs1)-v1(3)*ss1 v1(1)*v1(3)*(1-cs1)+v1(2)*ss1];
        R1(2,:) = [v1(1)*v1(2)*(1-cs1)+v1(3)*ss1 v1(2)*v1(2)*(1-cs1)+cs1 v1(2)*v1(3)*(1-cs1)-v1(1)*ss1];
        R1(3,:) = [v1(1)*v1(3)*(1-cs1)-v1(2)*ss1 v1(2)*v1(3)*(1-cs1)+v1(1)*ss1 v1(3)*v1(3)*(1-cs1)+cs1];

        %1-3 number tolls to parallel x axis. Rigid transformation on plane surface
        %Z axis coords oyler angle transform

        t = joint_3 - joint_1;
        d3 = R1(1,:) * t.';
        d3(1,2) = R1(2,:) * t.';
        d3(1,3) = R1(3,:) * t.';

        u3 = d3(1:2)/norm(d3(1:2));
        v3 = [u3(1) -u3(2)];
        v3(2,:) = [u3(2) u3(1)];
        u4 = [0 1].'; % decide orientation in plane

        csss = v3\u4;
        cs2 = csss(1);
        ss2 = csss(2);

        R2 = [cs2 -ss2 0];
        R2(2,:) = [ss2 cs2 0];
        R2(3,:) = [0 0 1];


        %apply rigid transformation
        for FN = 1:frame_num
            cur_body = bodyinfo(FN).bodies(1);
            joints = cur_body.joints;

            for JN = 1:25
                a = R1(1,:) * [joints(JN).x joints(JN).y joints(JN).z].';
                b = R1(2,:) * [joints(JN).x joints(JN).y joints(JN).z].';
                c = R1(3,:) * [joints(JN).x joints(JN).y joints(JN).z].';

                cur_subject_x(FN,JN) = R2(1,:) * [a b c].';
                cur_subject_y(FN,JN) = R2(2,:) * [a b c].';
                cur_subject_z(FN,JN) = R2(3,:) * [a b c].';

            end
        end

        %orientation normalize 2 (with plane surface)
        if cur_subject_y(1,4) < cur_subject_y(1,1)
            cur_subject_y = 0 - cur_subject_y;
        end

        if cur_subject_x(1,9) > cur_subject_x(1,5)
            cur_subject_x = 0 - cur_subject_x;
        end

        % for save origin subjects before data augment
        clear_subject_x = cur_subject_x;
        clear_subject_y = cur_subject_y;
        clear_subject_z = cur_subject_z;

        % Left <-> Right Change : 2option
        for LR = 1:2
            if LR == 1
                augment_x = clear_subject_x;
            else
                augment_x = 0 - clear_subject_x;
            end

            %Height change : 3option
            for HE = 1:3
                if HE == 1
                    augment_y = clear_subject_y.* 1.2;
                elseif HE==2
                    augment_y = clear_subject_y.* 1.0;
                else
                    augment_y = clear_subject_y.* 0.8;
                end

                %Give Gaussian Random Variable : 0.01 - 6times
                for RV = 1:6
                    %3. Gaussian Random filter 0.1
                    cur_subject_x = augment_x + 0.01.*randn(frame_num,25);
                    cur_subject_y = augment_y + 0.01.*randn(frame_num,25);
                    cur_subject_z = clear_subject_z + 0.01.*randn(frame_num,25);

                    % NORMALIZATION
                    cur_subject_y = cur_subject_y - min(cur_subject_y(:));
                    max_tall = max(cur_subject_y(:));
                    cur_subject_y = cur_subject_y ./ max_tall;

                    cur_subject_x = cur_subject_x - min(cur_subject_x(:));
                    cur_subject_x = cur_subject_x ./ max_tall;

                    cur_subject_z = cur_subject_z - min(cur_subject_z(:));
                    cur_subject_z = cur_subject_z ./ max_tall;


                    %Write image
                    motionpatch = cur_subject_x;
                    motionpatch(:,:,2) = cur_subject_y;
                    motionpatch(:,:,3) = cur_subject_z;

                    new_file_name = strcat('/home/rfj/바탕화면/actionGAN/DCGAN/new_motionpatch_rotate90/',file_name(1:20),'_',num2str(LR),num2str(HE),num2str(RV),'.png');
                    imwrite(motionpatch,new_file_name);

                end
            end

        end

    catch
        name
    end

end