Most of the cable network companies use the Disjoint Set Union data structure in Kruskal’s algorithm to find the shortest path to lay cables across a city or group of cities.
Which leads us to this post on the properties of Disjoint sets union and minimum spanning tree along with their example.
Before we proceed with an example of Kruskal’s algorithm, let’s first understand what disjoint sets are.
A disjoint set is a data structure which keeps track of all elements that are separated by a number of disjoint (not connected) subsets.
With the help of disjoints sets, you can keep a track of the existence of elements in a particular group.
Let’s say there are 6 elements A, B, C, D, E, and F. B, C, and D are connected and E and F are paired together.
This gives us 3 subsets that have elements (A), (B, C, D), and (E, F).
Disjoint sets help us quickly determine which elements are connected and close and to unite two components into a single entity.
A disjoint set data structure consists of two important functions:
Find() – It helps to determine which subset a particular element belongs to.
It also helps determine if the element is in more than one subset.
Union() – It helps to check whether a graph is cyclic or not. And helps connect or join two subsets.
For the previous example, we assume that for the set (B, C, D), B is a parent node.
For the disjoint set, we keep a single representative for each node.
If we search for an element in a particular node, it leads us to the parent of that particular node.
Therefore, when you search for D, the answer would be B.
Similarly, we can connect the subset (A) to (E, F ) which would result in node A as the parent node.
Now we have two subsets, but both B and A don’t have any parent node.
Each tree is an independent disjoint set, that is if two or more elements are in the same tree, they are part of the same disjoint set, else they are independent.
So if for a particular tree B is a representative, then Parent[i]=B.
If B is not a representative, we can move up the tree to find the parent or representative for the tree.
You can read more here about Basics of Disjoint sets.
Spanning tree is the sum of weights of all the edges in a tree.
A minimum spanning tree (MST) is one which costs the least among all spanning trees.
Here is an example of a minimum spanning tree.
Kruskal’s Algorithm and Prim’s minimum spanning tree algorithm are two popular algorithms to find the minimum spanning trees.
Kruskal’s algorithm uses the greedy approach for finding a minimum spanning tree.
Kruskal’s algorithm treats every node as an independent tree and connects one with another only if it has the lowest cost compared to all other options available.
Or as a simpler explanation,
Step 1 – Remove all loops and parallel edges
Step 2 – Arrange all the edges in ascending order of cost
Step 3 – Add edges with least weight
But how do you check whether two vertices are connected or not? That’s where the real-life example of Disjoint Sets come into use.
I am sure very few of you would be working for a cable network company, so let’s make the Kruskal’s minimum spanning tree algorithm problem more relatable.
On your trip to Venice, you plan to visit all the important world heritage sites but are short on time. To make your itinerary work, you decide to use Kruskal’s algorithm using disjoint sets.
Here is a map of Venice.
Let’s simplify the map by converting it into a graph as below and naming important locations on the map with letters and distance in meters (x 100).
Cannaregio | Ponte Scalzi | Santa Corce | Dell ‘Orto | Ferrovia | Piazzale Roma | San Polo | Dorso Duro | San Marco | St. Mark Basilica | Castello | Arsenale |
A | B | C | D | E | F | G | H | I | J | K | L |
Let’s understand how Kruskal’s algorithm is used in the real-world example using the above map.
Step 1- Remove all loops and parallel edges
So for the given map, we have a parallel edge running between Madonna dell’Orto (D) to St. Mark Basilica (J), which is of length 2.4kms(2400mts).
We will remove the parallel road and keep the 1.8km (1800m) length for representation.
Step 2 – Arrange all the edges on the graph in ascending order. Kruskal’s algorithm considers each group as a tree and applies disjoint sets to check how many of the vertices are part of other trees.
Step 3 – Add edges with least weight; we begin with the edges with least weight/cost. Hence, B, C is connected first considering their edge cost only 1.
I, J has cost 1; it is the edge connected next.
Then, we connect edges with weight = 2.
Similarly, we connect node K, L which has an edge with weight = 3.
As given in the table above, all the edges are connected in ascending order, ensuring no loop or cycle is formed between 2 vertices.
This gives us the following graph, which is the minimum spanning tree for the given problem.
#include <iostream> #include <vector> #include <utility> #include <algorithm> using namespace std; const int MAX = 1e4 + 5; int id[MAX], nodes, edges; pair <long long, pair<int, int> > p[MAX]; void initialize() { for(int i = 0;i < MAX;++i) id[i] = i; } int root(int x) { while(id[x] != x) { id[x] = id[id[x]]; x = id[x]; } return x; } void union1(int x, int y) { int p = root(x); int q = root(y); id[p] = id[q]; } long long kruskal(pair<long long, pair<int, int> > p[]) { int x, y; long long cost, minimumCost = 0; for(int i = 0;i < edges;++i) { // Selecting edges one by one in increasing order from the beginning x = p[i].second.first; y = p[i].second.second; cost = p[i].first; // Check if the selected edge is creating a cycle or not if(root(x) != root(y)) { minimumCost += cost; union1(x, y); } } return minimumCost; } int main() { int x, y; long long weight, cost, minimumCost; initialize(); cin >> nodes >> edges; for(int i = 0;i < edges;++i) { cin >> x >> y >> weight; p[i] = make_pair(weight, make_pair(x, y)); } // Sort the edges in the ascending order sort(p, p + edges); minimumCost = kruskal(p); cout << minimumCost << endl; return 0; }
After understanding how Kruskal’s algorithm works, it’s important to understand the difference between MST and TSP.
A minimum spanning tree helps you build a tree which connects all nodes, or as in the case above, all the places/cities with minimum total weight.
Whereas, a traveling salesman problem (TSP) requires you to visit all the places while coming back to your starting node with minimum total weight.
Following are some of the other real-life applications of Kruskal’s algorithm:
If you understood the example and working with disjoint sets, you are all set to join the CodeMonk challenge on the Disjoint Sets Union.
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