Can someone explain to me why is Prim's Algorithm using adjacent matrix result in a time complexity of O(V^{2})
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(Sorry in advance for the sloppy looking ASCII math, I don't think we can use LaTEX to typeset answers) The traditional way to implement Prim's algorithm with This way, we only ever check This on it's own wouldn't be enough as the original values in Without using Proof: To prove that without the To calculate which one to choose we must check each of these to find their minimum distance from the tree and then compare that to each other and find the minimum there. In the worst case scenario, each of the nodes contains a connection to each node in the tree, resulting in n * (Vn) edges and a complexity of Since our total would be the sum of each of these steps as n goes from 1 to V, our final time complexity is:
QED 


Note: This answer just borrows jozefg's answer and tries to explain it more fully since I had to think a bit before I understood it. BackgroundAn Adjacency Matrix representation of a graph constructs a V x V matrix (where V is the number of vertices). The value of cell (a, b) is the weight of the edge linking vertices a and b, or zero if there is no edge.
Prim's Algorithm is an algorithm that takes a graph and a starting node, and finds a minimum spanning tree on the graph  that is, it finds a subset of the edges so that the result is a tree that contains all the nodes and the combined edge weights are minimized. It may be summarized as follows:
AnalysisWe can now start to analyse the algorithm like so:
However, jozefg gave a good answer to show how to achieve O(V^2) complexity.
Here the distance vector represents the smallest weighted edge joining each node to the tree, and is used as follows:
Using these three steps reduces the searching time from O(E) to O(V), and adds an extra O(V) step to update the distance vector at each iteration. Since each iteration is now O(V), the overall complexity is O(V^2). 


First of all, it's obviously at least O(V^2), because that is how big the adjacency matrix is. Looking at http://en.wikipedia.org/wiki/Prim%27s_algorithm, you need to execute the step "Repeat until Vnew = V" V times. Inside that step, you need to work out the shortest link between any vertex in V and any vertex outside V. Maintain an array of size V, holding for each vertex either infinity (if the vertex is in V) or the length of the shortest link between any vertex in V and that vertex, and its length (so in the beginning this just comes from the length of links between the starting vertex and every other vertex). To find the next vertex to add to V, just search this array, at cost V. Once you have a new vertex, look at all the links from that vertex to every other vertex and see if any of them give shorter links from V to that vertex. If they do, update the array. This also cost V. So you have V steps (V vertexes to add) each taking cost V, which gives you O(V^2) 

