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It seems intuitive to solve a 2D dot-to-dot travelling salesman problem by eye using a greedy strategy. However we can only solve the TSP by eye if the graph is topographically accurate e.g. if A to B is 10 and A to C is 10 then B to C can't be 1000.

Is the greedy strategy still sub-optimal when we obey 2D scaling, ie travelling by plane? Below I managed to create a topographically accurate example where the greedy strategy is indeed sub optimal:

enter image description here

Starting at S:

  • Greedy: S B C A S => 2.83 + 4 + 5 + 2.2 => 14.03
  • Optimal: S A B C S => 2.2 + 3 + 4 + 3.16 => 12.36

Is there something special about the example above that will be common to all suboptimal greedy routes? Can geometry be used to minimize error?

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    This is probably a bit too much of a research-level question for Stack Overflow - you might want to try Computer Science, although I believe the thing you're looking for is called Euclidean TSP, which is also NP-hard, and has some well-known approximations. You're essentially asking for all special cases which can be solved greedily (since greedy would only be optimal by exception), which is possibly too broad. – Dukeling Jan 25 '18 at 23:33
  • Thanks @Dukeling Euclidean is the term I was lacking! I reposted there anyway! – david_adler Jan 25 '18 at 23:53
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I'm going to expand the comment of @Dukeling into a full answer since it seems to address the questions asked fairly well:

A graph is called a Euclidean graph if the vertices of the graph are associated with points in a plane and edges have weights equal to the distance between the points.

Solving TSP on Euclidean graphs is no easier than on general graphs.

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