I have a set of triangles. I am looking for a way to find all combinations of these triangles that constitute a convex hull when joined together. The convex hull should be empty, ie. no points inside the convex hull only on the edge. And only triangles that share a side can be joined together, ie. no gaps in the union.
Example: The following points gives 12 triangles (Delaunay Triangulation).
xy = [3.3735 0.7889; -0.1072 -3.4814; -3.9732 4.1955; -5 5; 5 5; 5 -5; -5 -5];
DT = delaunayTriangulation(xy);
triplot(DT);
%The coordinates for each triangle -- each row is a triangle.
TRIX = reshape(DT.Points(DT.ConnectivityList, 1), size(DT.ConnectivityList));
TRIY = reshape(DT.Points(DT.ConnectivityList, 2), size(DT.ConnectivityList));
I am looking for the largest convex hulls, so the convex hull should include as many triangles as possible. But if I have all the possible combinations I can easily filter out those with less triangles. In the example from above I should end up with these six convex hulls:
I am guessing that I should use that every triangle has at most three neighbouring triangles (one for each side). And that I should check whether the sum of the angle is less or equal 180 degrees at the points of intersect. This would insure that the union is convex -- see figure below. (The angle might also be exactly 360 degrees if several triangles form a full circle).
Triangle angles:
% Vectors connecting points
diffx = diff([TRIX TRIX(:,1)], [], 2); diffy = diff([TRIY TRIY(:,1)], [], 2); diffxy = [diffx(:) diffy(:)];
% Norm
normxy = reshape( arrayfun(@(row) norm(diffxy(row,:)), 1:size(diffxy,1)), size(DT.ConnectivityList));
nominator = repmat(sum(normxy.^2, 2), 1, 3) - 2*normxy.^2;
denominator = 2 * repmat(prod(normxy, 2), 1, 3)./normxy;
% Angle
tri_angle = acosd(nominator./denominator);
tri_angle = circshift(tri_angle, [0 -1]); % Shift so the angles match the correct point.
I reformat the information such that rows are points and columns are triangles:
n_tri = size(TRIX,1); % Number of triangles
% Adjacency matrix connecting points (rows) with triangles (columns).
adj_points = zeros(size(xy,1), n_tri);
adj_angle = NaN(size(adj_points));
for point =1:size(xy,1)
idx = find(DT.ConnectivityList == point);
[a_tri, ~] = ind2sub(size(DT.ConnectivityList), idx);
adj_points(point,a_tri) = 1;
adj_angle(point,a_tri) = tri_angle(idx);
end
I loop through all the edges and calculate the angles on both sides of the edge (edges angles
). This way I am able to find pairs of triangles that form a convex set (adj_convex
):
DT_edges = edges(DT); % All edges in the Delaunay triangulation
% Adjacency matrix connecting edges (rows) with triangles (columns).
adj_edge = logical(adj_points(DT_edges(:,1),:) .* adj_points(DT_edges(:,2),:));
edgesangles = NaN(size(DT_edges));
adj = zeros(n_tri); % Adjacency matrix indicating which triangles are neighbours.
adj_convex = zeros(n_tri);
for edge=1:size(DT_edges,1)
% The angles on either side of the edge.
tri = adj_edge(edge,:);
t = adj_angle(DT_edges(edge,:), tri );
edgesangles(edge,:) = sum(t, 2);
tri_idx = find(tri);
adj(tri_idx,tri_idx) = 1;
adj_convex(tri_idx,tri_idx) = prod(edgesangles(edge,:) <= 180);
end
convexedges = (edgesangles <= 180);
% Set diagonals to zero.
adj(logical(eye(n_tri))) = 0;
adj_convex(logical(eye(n_tri))) = 0;
However I am unsure how to proceed if I want all combinations, or the largest convex hull. And I am unsure how to account for the special case where several triangles from a full circle (ie. 360 degrees).