Approach: Greedy

The approach is to try to add the smallest edges as long as they do not create a cycle; add an edge to the tree that is minimum across the cut of ${\displaystyle T}$ vs. ${\displaystyle V-T}$. Unlike Dijkstra's algorithm, the weight of the crossing edge is directly considered (as opposed to the distance from the source node).

Given the MST of ${\displaystyle V_{n-m}=v_{1},v_{2},\ldots ,v_{n-m}}$, the MST of ${\displaystyle V}$ should be that of ${\displaystyle V_{n-1}}$ plus the edge that connects to ${\displaystyle v_{n}}$ that is the shortest.

${\displaystyle OPT(n)=OPT(n-1)+min((v_{i},v_{n})\in E)}$

Implementation

for each u in V:
    key[u] = infinity   // cost array
    pi[u] = infinity    // from array
Q = new PriorityQueue(V)
key[root] = 0
while Q is not empty:
    u = extractMin(Q)
    # Reduce nodes
    for v in adj[u]:
        if v in Q and w[u,v] < key[v]:
            key[v] = w[u,v]

Analysis

Priority queue is slower than array when the graph is dense, so sometimes it's better to use Dijsktra's algorithm.

Proof: Greedy

Greeedy strategy: Let the greedy choice be the edge that is smallest that crosses the cut between ${\displaystyle A}$ and ${\displaystyle V-A}$.

Name greedy choice: let ${\displaystyle r\rightarrow x}$ be the smallest edge that crosses the cut from ${\displaystyle A=r}$ and ${\displaystyle V-r}$.

Given an optimal solution with (r,y), prove that ${\displaystyle A=OPT-(r,y)+(r,x)}$ is still optimal.

${\displaystyle A}$ is still a tree since there is no cycles created.

${\displaystyle w(r,y)\geq w(r,x)}$ due to its properties as the greedy choice.

Therefore, ${\displaystyle A}$ must be optimal.