# Optimizing the layout of a graph with given (erroneous) node-distances

I have a loosely connected graph. For every edge in this graph, I know the approximate distance d(v,w) between node v and w at positions p(v) and p(w) as a vector in R3, not only as an euclidean distance. The error shall be small (lets say < 3%) and the first node is at <0,0,0>.

If there were no errors at all, I can calculate the node-positions this way:

``````set p(first_node) = <0,0,0>
calculate_position(first_node)

calculate_position(v):
for (v,w) in Edges:
if p(w) is not set:
set p(w) = p(v) + d(v,w)
calculate_position(w)
for (u,v) in Edges:
if p(u) is not set:
set p(u) = p(v) - d(u,v)
calculate_position(u)
``````

The errors of the distance are not equal. But to keep things simple, assume the relative error (d(v,w)-d'(v,w))/E(v,w) is N(0,1)-normal-distributed. I want to minimize the sum of the squared error

``````sum( ((p(v)-p(w)) - d(v,w) )^2/E(v,w)^2 ) for all edges
``````

The graph may have a moderate amount of Nodes ( > 100 ) but with just some connections between the nodes and have been "prefiltered" (split into subgraphs, if there is only one connection between these subgraphs).

I have tried a simplistic "physical model" with hooks low but its slow and unstable. Is there a better algorithm or heuristic for this kind of problem?

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This looks like linear regression. Take error terms of the following form, i.e. without squares and split into separate coordinates:

``````(px(v) - px(w) - dx(v,w))/E(v,w)
(py(v) - py(w) - dy(v,w))/E(v,w)
(pz(v) - pz(w) - dz(v,w))/E(v,w)
``````

If I understood you correctly, you are looking for values `px(v)`, `py(v)` and `pz(v)` for all nodes `v` such that the sum of squares of the above terms is minimized.

You can do this by creating a matrix A and a vector b in the following way: every row corresponds to one of equation of the above form, and every column of A corresponds to one variable, i.e. a single coordinate. For n vertices and m edges, the matrix A will have 3m rows (since you separate coordinates) and 3n−3 columns (since you also fix the first node `px(0)=py(0)=pz(0)=0`).

The row for `(px(v) - px(w) - dx(v,w))/E(v,w)` would have an entry `1/E(v,w)` in the column for `px(v)` and an entry `-1/E(v,w)` in the column for `px(w)`. All other columns would be zero. The corresponding entry in the vector b would be `dx(v,w)/E(v,w)`.

Now solve the linear equation (AT·A)x = AT·b where AT denotes the transpose of A. The solution vector x will contain the coordinates for your vertices. You can break this into three independent problems, one for each coordinate direction, to keep the size of the linear equation system down.

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I had a similar idea on the next day. Least squares -- yet again;) Good point for solving each dimension on its own. Thank you. –  Peter Schneider May 7 '13 at 10:29