# Finding a subgraph of max weight

I have a city area (let's think of it as a graph of streets), where all streets have some weight and length associated with them. What I want to do is find a connected set of streets, located near other, with some max (or close to max) total weight W, given that my max subgraph can only contain up to N streets.

I'm specifically not interested in a subgraph that would span the entire graph, but rather only a small cluster of streets that has max or close to max combined weight and where all streets are located "near" each other, where "near" would be defined as no street being more than X meters away from the center of the cluster. Resulting subgraph would have to be connected.

Does anyone know if the name for this algorithm assuming it exists?

Also interested in any solutions, exact or approximations.

To show this visually, assume my graph is all the street segments (intersection to intersection) in the image below. So individual street is not Avenue A, it's Avenue A between 10th and 11th, and so on. Street will either have weight of 1 or 0. Assume that the set of streets with max weights are in the selected polygon - what I want to do is find this polygon. • Similatlr problem math.stackexchange.com/questions/1824344/… (in general, CS- and math-oriented exchanges are better for this kind of questions). – n. 'pronouns' m. Oct 23 '17 at 6:23
• What does "near" mean in this context? At which weight do i choose the further away street? Is there a function that you try to maximize? – fafl Oct 23 '17 at 8:59
• Near here would be a parameter, but typically within 5 blocks or so. So I'm looking at maybe 2-3 square mile graph of streets, from which I want to pick out maybe 0.5x0.5 (roughly, doesn't have to be square) area of max combined weight – kozyr Oct 23 '17 at 15:30
• 'where "near" would be defined as no street being more than X meters away from the center of the cluster. ' I suggest a simple algorithm that pick each node as center and use a shortest path to search for "close street", and return the the cluster with highest weight. I guess the number of nodes would not be too many, maybe at most 10000? For this data size, the result should be ready within a few secs. what do you think about it? – Petar Petrovic Oct 27 '17 at 7:42
• Presumably streets are curves in the plane, so what is "the distance" between two streets? Is it, for example, the smallest distance between any point on the first street and any point on the second? I suppose you will say "yes", so the next question is: It is then possible that streets A and B are "close enough", and streets B and C are "close enough", but streets A and C are not "close enough". Do you require every pair of streets to be "close enough"? Separately, can we assume that two street vertices are linked by an edge iff those streets intersect? – j_random_hacker Oct 28 '17 at 13:30

Here's a proposal. Consider each vertex in the graph of nodes as the "center" as you've defined it. For each center C[i], execute Dijkstra's algorithm to construct a shortest path tree with C[i] as the origin. Stop constructing the tree when it would include a vertex more than the max allowed from the center.

Then let A[i] be the set of all edges incident to vertices in the tree centered on V[i]. The result will be the set A[i] with maximum weight.

The run time of one execution of Dijkstra's algorithm is O(|E[i]| + |V[i]| log |V[i]|) for the ith center. The sets here are limited in size by the max distance from center. Total cost is sum_(i in 1..|V|) O(|E[i]| + |V[i]| log |V[i]|). In the degenerate case where the max allowable weight allows the whole graph to be included from each center, cost will be O(|V| (|E| + |V| log |V|)).

I can think of some possible optimizations to improve run time, but want to verify this gets at the problem you have in mind.

• So this would work, but I don't think it will find the max weight cluster. – kozyr Oct 30 '17 at 16:04
• If, let's say, you have a street in the center, and all streets to the left of it have high weight (let's say weights are either 0 or 1 for simplicity, so all streets to the left have weight of 1), then we would have a shortest path that includes, let's say, 10 streets going left with total weight of 10. However, if there are also 10 streets on the right with a weight of 1, those will not be considered, as they are not part of our shortest path. Our max weight here should be 20, but instead will be 10, either from going left or right - assume that our max allowed distance from center is 10 sts – kozyr Oct 30 '17 at 16:10
• @kozyr That's as may be, but it's not how you defined the problem. Your words: "where "near" would be defined as no street being more than X meters away from the center" – Gene Oct 30 '17 at 22:26
• well, I used 10 streets here as a metric for simplicity. Assume that each street is 100 meters long, so if we go left 1000 meters (10 streets), and our X (radius) here is 1000, then we have the issue I described - there are 10 more streets that we can include within the right 1000 meters, for max weight of 20 instead of 10. – kozyr Oct 30 '17 at 23:56

Here is an integer programming exact formulation for the problem assuming you have a finite number of total streets, S, and the "center" of a cluster can be one of the finite number of streets S. If you are looking at a cluster center in continuous Euclidean space, that is going to take us into the domain of the Weber Problem. That may still be doable, but we would have to look at a column-generation formulation. Objective function maximizes the weight of selected streets indexed by j. Constraint (1) specifies that exactly one center be chosen. Constraint (2) specifies that for any potential center, i, only N streets are chosen as neighbors. Constraint (3) stipulates that a street is chosen as part of some neighborhood only if the corresponding center is chosen. The rest are binary integer constraints.

If the street chosen as center counts as one of the N streets, it is easy to enforce by specifying y_{ii} = x_i

Note: If the above formulation is right, or captures the problem accurately, [MIP] can be solved trivially, once set N_i has been identified.

Consider each i in turn. From N_i pick the top N neighboring streets in descending order of weight. This is your incumbent solution. Update incumbent solution if better solution is found as you iterate through the is.

• If I understand this correctly, this solution will return top M streets out of N_i, but there's no guarantee that those streets will be connected. Yes, they are neighbors of i, but the result might end up being two disconnected sets of streets around street i, whereas I'm only interested in connected subset of streets. – kozyr Oct 31 '17 at 22:47
• In that case, if every pair of streets in your solution have to be connected, you are looking for the cardinality constrained maximum clique problem. See a paper on that people.mpi-inf.mpg.de/~nmegow/papers/ctw09.pdf – Tryer Nov 1 '17 at 0:57
• Not every pair though. The result should be a connected graph, but it doesn't have to be fully connected. – kozyr Nov 2 '17 at 6:50
• A neighbor of i, N_i, by definition is the set of all nodes connected to i. So, if i is selected, as my original answer indicated, all of the neighbors of i will be connected to each other via i. Can you be more clear about what it means for two streets/nodes to be connected? – Tryer Nov 2 '17 at 6:55
• Updated my original question with a picture. Regarding the neighbors - neighbor of street_i is any street reachable from street_i, within max distance N. The final set of streets (street_i and its neighbors) should be connected. – kozyr Nov 3 '17 at 6:13