# Tag Info

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You have Warshalls algorithm for that, here is pseudocode Warshall(A) P=A for k=1 to n do for k=1 to n do for k=1 to n do p[i,j]=p[i,j] or (p[i,k] and p[k,j]) end_for end_for end_for And implementation depends on your data sturcture. Also you may use Floyd or Dijkstra algorithm

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You only need a DFS/BFS to check for cicles. You need to mark visited nodes. If you reach again a visited node, which is not the node that you came from (so you need to know the last node you visited), then you find a cycle. So, besides the classic BFS/DFS, you need to perform 2 aditional checks: if you reached a node that has already been visited (this you ...

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Your confusion is stemming from the fact that you apparently assume that DFS algorithm can be obtained from BFS algorithm by replacing the FIFO queue with a LIFO stack. This is a popular misconception, but it is simply not true. The classic DFS algorithm is not obtained by replacing the BFS queue with a stack. The difference between these algorithms is ...

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In DFS you need only space for linear to the depth O(log(n) on a fully balanced tree while BFS (Breadth-first search) needs O(n) (The widest part of the tree is the lowest depth which has in a binary tree n/2 nodes). Example: 1 / \ / \ / \ / \ / \ ...

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In DFS, the space used is O(h) where h is the height of the tree. In BFS, the space used is O(w) where w is the 'width' of the tree. In typical binary trees (i.e. random binary trees), w = Omega(n) and h = O(sqrt(n)). In balanced trees, w = Omega(n) and h = O(log n).

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actually both measures are right. The one computed by NodeXL is the closeness centrality and the other computer by Gephi is the inverse closeness centrality. Therefore, in the case of inverse closeness centrality the higher the value, the close to the center. The difference between both centralities lies in consideration of graph sizes and efficiency. The ...

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1. Bugs When I run your code I get the following error: >>> backtrace(path_holder, 'node1', 'GOAL') Traceback (most recent call last): File "<stdin>", line 1, in <module> File "q20349609.py", line 13, in backtrace dct.update(d) ValueError: dictionary update sequence element #0 has length 1; 2 is required That's because when ...

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Actually, if the graph is extremely large, you will need to use Dijkstra's algorithm in order to find the shortest distance. So it depends on how many nodes the OP's graph has.

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You can try with a backtracking. In each step for one of 'leaf' vertices decide how many 'out' edges to use. function add_some_vertex_edges(leaves, edge): if |leaves| == |V|: num_of_MSTs += 1 return v = leaves.pop() # takes one vertex and removes it from leaves let v_edge be set of incident edges to v that are not already in edges and that ...

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Most scaling algorithms effectively set "springs" between nodes, where the resting length of the spring is the desired length of the edge. They then attempt to minimize the energy of the system of springs. When you initialize all the nodes on top of each other though, the amount of energy released when any one node is moved is the same in every direction. So ...

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I'm running around trying to close out old problems here on SO. I hope it still helps this late. I tackled a similar problem in matlab a couple of months ago. G is your problem. G tells you what the difficulty is to move from your starting location along a path, it is not a heuristic. It is knowable and you don't need to estimate it. In your case of only ...

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A singly connected component is any directed graph belonging to the same entity. It may not necessarily be a DAG and can contain a mixture of cycles. Every node has atleast some link(in-coming or out-going) with atleast one node for every node in the same component. All we need to do is to check whether such a link exists for the same component. Singly ...

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I think the problem may be in your implementation of union: public static void union(int x, int y){ parent[x-1] = y; } the problem is if x already has been joined into a set, it will already have a parent which you override. The solution is to join the root of the two candidates instead of the leaf nodes: public static void union(int x, int y){ ...

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Alternative solution is to use a trie with all the valid words. You can utilize it's structure to efficiently prune the search space. The rough upper bound on the number of possible combinations, for 5x5 board with words up to 11 letters, is 100,000,000 words. Most of which would not be valid words (like TNPU in the last row of the image). So with proper ...

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Disclaimer: I have only seen such a game, not implemented anything like it. You can do it with some backtracking algorithm, which generates the words and searches them in a dictionary. However, this will be extremely slow for 5x5 board. So what you can do is to search for the amount of words that you can further generate if you have already generated some ...

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Since you only want a hint, work out the solution for small n, and you should be able to see a generalization to a greater n. You had a good start and you can get to the answer if you work a little more. For small n's I have the following values starting at n = 3: {5, 7, 9, 11, 13}.

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It seems like you are on the right track. The graph starts with a "capacity" to add 4*n edges. Each new node reduces the total edge capacity by 2. This can be solved with simple algebra. The only remaining question is can you find a edge assignment scheme which prevents situations where you have enough edge capacity but not enough nodes.

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As Jan commented, question isn't specific what a goal is. If you want to minimize tree weight problem is called generalized Steiner tree. If you want any kind of spanning tree between these nodes, you can make minimum spanning tree on graph with set of nodes you want to connect and edges that connect each pair of nodes with a shortest path between them. ...

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The arrays have zero based indexes. But your first two loops start from 1: for(i=1; i < nodes;i++) So this will likely cause that fact that it works when you start first=0, because in your adjacency matrix AMatrix[current][i] != 0 the diagonal (current == i) is probably 0. But if you start the algorithm with an other value that 0, you are missing a ...

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Here, for bipartite graphs, n1 denotes number of vertices of the first set (partition) and n2 denotes number of vertices of the second set. E.g. you would have a set of workers and a set of tasks they would perform. In the example above, there are 2 workers (say John=0 and Bob=1) and three tasks (say, coding=0, QA=1, support=2). John can do coding and ...

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I think you can modify Dijkstra's algorithm to solve this problem. With Dijkrasta's algorithm you are solving the shortest path. Just change that to find the maximum path. To restrict it to only 1,2,3 nodes in a graph, keep track of the number of nodes it takes to get to each node when you "visit it". Stop when there are no other nodes with a count less ...

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https://class.coursera.org/algo2-2012-001/lecture/index see week4 slides and video for more details.

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I'm going to assume that the numbers in the brackets are the estimated distances from a given node to the goal using some heuristic (at first glance they seem to be consistent with an admissible heuristic function). If this is the case, then this is the h(x) in the cost equation: f(x) = g(x) + h(x) g(x) would be the actual cost of the path from the ...

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after coming back to this after a while, I realized a normal BFS doesn't actually work because there is no way to tell how far you've travelled from the root node. I implemented a BFS with a stack instead, so its similar to a dfs

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I don't think there are any standard algorithms that will give you what you want. You're going to have to get creative. Assuming your points are embedded in 2D Euclidean space here are some ideas: Iteratively compute several convex hulls. For example, compute the convex hull, keep the points that are part of the convex hull, then compute another convex ...

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This sounds like Connected Dominating Set.

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In my opinion, RELAX takes O(1). Since every edge is looked at exactly once, this generates O(E). Point is that extract-min takes O(log(V)) and is used V times, which accounts for O(V log(V)). So all in all, Djikstra runs in O(V log V + E)(see this page), independent of which heap structure is used (see this post). Aside of that, running min-heap whenever ...

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A very simple solution (but maybe not the one with lowest complexity) would be to use a quad tree for all your edges based on their bounding box. Then you simply extract the set of edges closest to your query point and iterate over them to find the closest edge. The extracted set of edges returned by the quad tree should be many factors smaller than your ...

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You should be able to do this in O(n^2 logn). For each point, sort all other points by distance. Since a square needs two equidistant points and one that is that distance times sqrt(2), you can easily find candidate groups. Once you do, there are several methods to check a group for squareness. for each point a sort other points by distance to a ...

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Here is a simple algorithm to check for quadruples:- sort all pairs of points according to slopes breaking ties with lesser length one coming first. scan the sorted list and check for adjacent pair to current pair with same length & slope. if found such pair find its parallel distance and check if it is same as length. If so then the quadruple form a ...

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There is simple O(n^3) algorithm. Take a pair of points (black). For this pair we can check other points as possible candidates to form a square - green and red places. If we have found both green points or both red points then output square(s) formed by initial pair and by these points. Pseudocode: for i = 0 to n-4 do for j = i+1 to n-3 do Calc ...

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You are right it is a TSP, but what you need to do is too reduce the graph so it only contains nodes that are to be visited. How to reduce the graph is left as an exercise for the reader ;-)

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The R-Tree is an data structure designed for this kind of thing. Boost contains an implementation of it. As does CGAL. Most modern databases support this kind of thing natively as well.

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There are a lot of algorithms out there doing this. The catchword is path-finding. The best algorithm to learn from at the beginning is the good old Dijkstra http://en.wikipedia.org/wiki/Dijkstra%27s_algorithm Then for larger graphs (that are no maze) you might want an algorithm with some direction heuristics making evaluation faster like the A* algorithm. ...

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First of all, the algorithm displayed on your image from the pdf file is not a solution to the Hamilton path problem but a solution to a maze generation as the final path has several branches. To find algorithms for a maze generation, see: https://en.wikipedia.org/wiki/Maze_generation_algorithm Now here is a simple algorithm to generate a Hamiltonian path ...

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Without proof: You start with a constrained Delaunay Triangulation, that is a triangulation that takes the existing edges into account. E.g. CGAL or Triangle can do this. For each query point you determine which triangle it belongs to. Then you you only have to check the edges touching a corner of that triangle. I think this should work in most cases, ...

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I believe there is a way to solve this in linear time. While searching the graph with depth-first-search (DFS has a runtime of O(V+E)), you can keep track of the distance from the source to the current node (by simply incrementing the parent's distance with the weight of the edge connecting the child node to the parent). Then, whenever you encounter a cycle ...

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I think that you are looking for the set of articulation points in a graph! if so, this is an application of Depth-First Search: http://www.geeksforgeeks.org/articulation-points-or-cut-vertices-in-a-graph/

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Add 3 new nodes, named C1, C2 and C3 by colour they represent. Add edges between new nodes (C1,C2), (C2,C3) and (C1,C3). If three_colorability(V,E) is true than three_colorability(V+{C1,C2,C3},E+{(C1,C2),(C2,C3),(C1,C3)}) is also true. For each (original) vertex v, three_colorability() returns true for at least one of graphs with added two edge of {(v,C1), ...

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Answering my own question here... In the absence of upper-bounds, the easiest way -- easiest to implement, understand, and that is reasonably efficient -- to find the minimum flow of a graph is the following: Find a feasible flow, i.e. a flow that satisfies flow rules and lower-bounds on flow but isn't necessarily a minimum flow. This can be accomplished ...

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Here is an algorithm to derive a structure to help solve the cycle count problem: For each node, derive the indegree (the number of incoming edges) and the outdegree. Remove all nodes with indegree zero. Those are not part of a cycle. From their successors, subtract 1 from the indegree. From their predecessors, subtract 1 from the outdegree. Remove all ...

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If there is exactly one directed path between every pair of nodes, then every node must have at least one out-edge (else no paths from that node to other nodes) no node can have have more than one out-edge (if there is an edge from X to Y and an edge from X to Z, and there are paths from Y to T and from Z to T, then there are multiple paths from X to T) ...

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Removing a vertex with degree two can create multiple copies of edges: original edge: (u,v), (v,w), (u,w) after removing v: (u, w), (u, w) Removing multiple copies of edges can create a vertex with degree two: original edge: (u,v), (v,w), (v,w) after removing (v,w): (u, v), (v, w)

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in a graph of four vertexes, w, x, y, z w *----- x -----* y ------- z | | *---------------* if you replace (w, x) and (x, y) with (w, y) using replaces rule, than it looks like, there are two parallel edges from w to y. if you remove duplicate edges, than the graph, will look like: w --------------- y ------- z so now if ...

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The process of building a spanning tree using BFS over an undirected graph would generate the following types of edges: Tree edges Cross edges (connecting vertices on different branches) A simple example: Imagine a triangle (a tri-vertice clique) - start a BFS from any node, and you'll reach the other two on the first step. You're left with an edge ...

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An SQL database might be a good answer. If you imagine a table like (bucketId, latNe, longNe, latSw, longSw), with indices on all the lat/long columns, then you could very efficiently get an answer by preparing and executing a query like SELECT bucketId FROM bucketTable WHERE latNe > ? AND longNe < ? AND latSe < ? AND longSe > ? using the ...

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You need to subdivide the list of ranges. You can look into a quadkey. It's similar to a quadtree. It uses a morton curve. You can very fast compute the quadkey of the range and the points. But you can also try a rectangle tree. You can also use an intervall tree.

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Path by Hcycle(V,E): Call Hcycle() on a graph created by adding one vertex that is connected to all other vertices. If new graph has a cycle than removing new node from that cycle we get path on original graph. Cycle by Hpath(V,E): Call Hpath() on a graph created by adding one vertex and connecting it to same neighbours as one existing vertex. That means ...

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There are spatial query structures which are appropriate for other types of data than points. The most general is the "R-tree" structure (and its many, many variants), which will allow you to store the bounding rectangles of your line segments. You can then search outward from your query points, examining the segments in the bounding rectangles and stopping ...

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You can compute the voronoi diagram and run a query on each voronoi cell. You can subdivide the voronoi diagram to get a better result. You can combine metric and voronoi diagram:http://www.cc.gatech.edu/~phlosoft/voronoi/

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