Je-li daný souvislý a neorientovaný graf, kostra tohoto grafu je podgrafem, který je stromem a spojuje všechny vrcholy dohromady. Jeden graf může mít mnoho různých kostry. Minimální kostra součinu pro vážený spojený a neorientovaný graf je kostra s hmotnostním součinem menším nebo rovným hmotnostnímu součinu každé jiné kostry. Hmotnostní součin kostry je součin vah odpovídajících každé hraně kostry. Všechny váhy daného grafu budou pro jednoduchost kladné.
Příklady:
Minimum Product that we can obtain is 180 for above graph by choosing edges 0-1 1-2 0-3 and 1-4
Tento problém lze vyřešit pomocí standardních algoritmů minimálního spanning tree, jako je Kruskal ( https://www.geeksforgeeks.org/dsa/kruskals-minimum-spanning-tree-algorithm-greedy-algo-2/ )a prim 's algoritmus, ale musíme upravit náš graf, abychom tyto algoritmy používali. Algoritmy minimálního spanning tree se snaží minimalizovat celkový součet vah, zde musíme minimalizovat celkový součin vah. Můžeme použít vlastnost logaritmy překonat tento problém.
Jak víme
log(w1* w2 * w3 * …. * wN) = log(w1) + log(w2) + log(w3) ….. + log(wN)
Každou váhu grafu můžeme nahradit její logaritmickou hodnotou, pak použijeme libovolný algoritmus minimálního spanning tree, který se pokusí minimalizovat součet log(wi), což zase minimalizuje váhový součin.
Kroky jsou uvedeny například v grafu níže
V níže uvedeném kódu jsme nejprve vytvořili log graf z daného vstupního grafu, poté je tento graf dán jako vstup do primova MST algoritmu, který minimalizuje celkový součet vah stromu. Protože váhy upraveného grafu jsou logaritmy aktuálního vstupního grafu, minimalizujeme vlastně součin vah kostry.
// A C++ program for getting minimum product // spanning tree The program is for adjacency matrix // representation of the graph #include
// A Java program for getting minimum product // spanning tree The program is for adjacency matrix // representation of the graph import java.util.*; class GFG { // Number of vertices in the graph static int V = 5; // A utility function to find the vertex with minimum // key value from the set of vertices not yet included // in MST static int minKey(int key[] boolean[] mstSet) { // Initialize min value int min = Integer.MAX_VALUE min_index = 0; for (int v = 0; v < V; v++) { if (mstSet[v] == false && key[v] < min) { min = key[v]; min_index = v; } } return min_index; } // A utility function to print the constructed MST // stored in parent[] and print Minimum Obtainable // product static void printMST(int parent[] int n int graph[][]) { System.out.printf('Edge Weightn'); int minProduct = 1; for (int i = 1; i < V; i++) { System.out.printf('%d - %d %d n' parent[i] i graph[i][parent[i]]); minProduct *= graph[i][parent[i]]; } System.out.printf('Minimum Obtainable product is %dn' minProduct); } // Function to construct and print MST for a graph // represented using adjacency matrix representation // inputGraph is sent for printing actual edges and // logGraph is sent for actual MST operations static void primMST(int inputGraph[][] double logGraph[][]) { int[] parent = new int[V]; // Array to store constructed MST int[] key = new int[V]; // Key values used to pick minimum // weight edge in cut boolean[] mstSet = new boolean[V]; // To represent set of vertices not // yet included in MST // Initialize all keys as INFINITE for (int i = 0; i < V; i++) { key[i] = Integer.MAX_VALUE; mstSet[i] = false; } // Always include first 1st vertex in MST. key[0] = 0; // Make key 0 so that this vertex is // picked as first vertex parent[0] = -1; // First node is always root of MST // The MST will have V vertices for (int count = 0; count < V - 1; count++) { // Pick the minimum key vertex from the set of // vertices not yet included in MST int u = minKey(key mstSet); // Add the picked vertex to the MST Set mstSet[u] = true; // Update key value and parent index of the // adjacent vertices of the picked vertex. // Consider only those vertices which are not yet // included in MST for (int v = 0; v < V; v++) // logGraph[u][v] is non zero only for // adjacent vertices of m mstSet[v] is false // for vertices not yet included in MST // Update the key only if logGraph[u][v] is // smaller than key[v] { if (logGraph[u][v] > 0 && mstSet[v] == false && logGraph[u][v] < key[v]) { parent[v] = u; key[v] = (int)logGraph[u][v]; } } } // print the constructed MST printMST(parent V inputGraph); } // Method to get minimum product spanning tree static void minimumProductMST(int graph[][]) { double[][] logGraph = new double[V][V]; // Constructing logGraph from original graph for (int i = 0; i < V; i++) { for (int j = 0; j < V; j++) { if (graph[i][j] > 0) { logGraph[i][j] = Math.log(graph[i][j]); } else { logGraph[i][j] = 0; } } } // Applying standard Prim's MST algorithm on // Log graph. primMST(graph logGraph); } // Driver code public static void main(String[] args) { /* Let us create the following graph 2 3 (0)--(1)--(2) | / | 6| 8/ 5 |7 | / | (3)-------(4) 9 */ int graph[][] = { { 0 2 0 6 0 } { 2 0 3 8 5 } { 0 3 0 0 7 } { 6 8 0 0 9 } { 0 5 7 9 0 } }; // Print the solution minimumProductMST(graph); } } // This code has been contributed by 29AjayKumar
# A Python3 program for getting minimum # product spanning tree The program is # for adjacency matrix representation # of the graph import math # Number of vertices in the graph V = 5 # A utility function to find the vertex # with minimum key value from the set # of vertices not yet included in MST def minKey(key mstSet): # Initialize min value min = 10000000 min_index = 0 for v in range(V): if (mstSet[v] == False and key[v] < min): min = key[v] min_index = v return min_index # A utility function to print the constructed # MST stored in parent[] and print Minimum # Obtainable product def printMST(parent n graph): print('Edge Weight') minProduct = 1 for i in range(1 V): print('{} - {} {} '.format(parent[i] i graph[i][parent[i]])) minProduct *= graph[i][parent[i]] print('Minimum Obtainable product is {}'.format( minProduct)) # Function to construct and print MST for # a graph represented using adjacency # matrix representation inputGraph is # sent for printing actual edges and # logGraph is sent for actual MST # operations def primMST(inputGraph logGraph): # Array to store constructed MST parent = [0 for i in range(V)] # Key values used to pick minimum key = [10000000 for i in range(V)] # weight edge in cut # To represent set of vertices not mstSet = [False for i in range(V)] # Yet included in MST # Always include first 1st vertex in MST # Make key 0 so that this vertex is key[0] = 0 # Picked as first vertex # First node is always root of MST parent[0] = -1 # The MST will have V vertices for count in range(0 V - 1): # Pick the minimum key vertex from # the set of vertices not yet # included in MST u = minKey(key mstSet) # Add the picked vertex to the MST Set mstSet[u] = True # Update key value and parent index # of the adjacent vertices of the # picked vertex. Consider only those # vertices which are not yet # included in MST for v in range(V): # logGraph[u][v] is non zero only # for adjacent vertices of m # mstSet[v] is false for vertices # not yet included in MST. Update # the key only if logGraph[u][v] is # smaller than key[v] if (logGraph[u][v] > 0 and mstSet[v] == False and logGraph[u][v] < key[v]): parent[v] = u key[v] = logGraph[u][v] # Print the constructed MST printMST(parent V inputGraph) # Method to get minimum product spanning tree def minimumProductMST(graph): logGraph = [[0 for j in range(V)] for i in range(V)] # Constructing logGraph from # original graph for i in range(V): for j in range(V): if (graph[i][j] > 0): logGraph[i][j] = math.log(graph[i][j]) else: logGraph[i][j] = 0 # Applying standard Prim's MST algorithm # on Log graph. primMST(graph logGraph) # Driver code if __name__=='__main__': ''' Let us create the following graph 2 3 (0)--(1)--(2) | / | 6| 8/ 5 |7 | / | (3)-------(4) 9 ''' graph = [ [ 0 2 0 6 0 ] [ 2 0 3 8 5 ] [ 0 3 0 0 7 ] [ 6 8 0 0 9 ] [ 0 5 7 9 0 ] ] # Print the solution minimumProductMST(graph) # This code is contributed by rutvik_56
// C# program for getting minimum product // spanning tree The program is for adjacency matrix // representation of the graph using System; class GFG { // Number of vertices in the graph static int V = 5; // A utility function to find the vertex with minimum // key value from the set of vertices not yet included // in MST static int minKey(int[] key Boolean[] mstSet) { // Initialize min value int min = int.MaxValue min_index = 0; for (int v = 0; v < V; v++) { if (mstSet[v] == false && key[v] < min) { min = key[v]; min_index = v; } } return min_index; } // A utility function to print the constructed MST // stored in parent[] and print Minimum Obtainable // product static void printMST(int[] parent int n int[ ] graph) { Console.Write('Edge Weightn'); int minProduct = 1; for (int i = 1; i < V; i++) { Console.Write('{0} - {1} {2} n' parent[i] i graph[i parent[i]]); minProduct *= graph[i parent[i]]; } Console.Write('Minimum Obtainable product is {0}n' minProduct); } // Function to construct and print MST for a graph // represented using adjacency matrix representation // inputGraph is sent for printing actual edges and // logGraph is sent for actual MST operations static void primMST(int[ ] inputGraph double[ ] logGraph) { int[] parent = new int[V]; // Array to store constructed MST int[] key = new int[V]; // Key values used to pick minimum // weight edge in cut Boolean[] mstSet = new Boolean[V]; // To represent set of vertices not // yet included in MST // Initialize all keys as INFINITE for (int i = 0; i < V; i++) { key[i] = int.MaxValue; mstSet[i] = false; } // Always include first 1st vertex in MST. key[0] = 0; // Make key 0 so that this vertex is // picked as first vertex parent[0] = -1; // First node is always root of MST // The MST will have V vertices for (int count = 0; count < V - 1; count++) { // Pick the minimum key vertex from the set of // vertices not yet included in MST int u = minKey(key mstSet); // Add the picked vertex to the MST Set mstSet[u] = true; // Update key value and parent index of the // adjacent vertices of the picked vertex. // Consider only those vertices which are not yet // included in MST for (int v = 0; v < V; v++) // logGraph[u v] is non zero only for // adjacent vertices of m mstSet[v] is false // for vertices not yet included in MST // Update the key only if logGraph[u v] is // smaller than key[v] { if (logGraph[u v] > 0 && mstSet[v] == false && logGraph[u v] < key[v]) { parent[v] = u; key[v] = (int)logGraph[u v]; } } } // print the constructed MST printMST(parent V inputGraph); } // Method to get minimum product spanning tree static void minimumProductMST(int[ ] graph) { double[ ] logGraph = new double[V V]; // Constructing logGraph from original graph for (int i = 0; i < V; i++) { for (int j = 0; j < V; j++) { if (graph[i j] > 0) { logGraph[i j] = Math.Log(graph[i j]); } else { logGraph[i j] = 0; } } } // Applying standard Prim's MST algorithm on // Log graph. primMST(graph logGraph); } // Driver code public static void Main(String[] args) { /* Let us create the following graph 2 3 (0)--(1)--(2) | / | 6| 8/ 5 |7 | / | (3)-------(4) 9 */ int[ ] graph = { { 0 2 0 6 0 } { 2 0 3 8 5 } { 0 3 0 0 7 } { 6 8 0 0 9 } { 0 5 7 9 0 } }; // Print the solution minimumProductMST(graph); } } /* This code contributed by PrinciRaj1992 */
<script> // A Javascript program for getting minimum product // spanning tree The program is for adjacency matrix // representation of the graph // Number of vertices in the graph let V = 5; // A utility function to find the vertex with minimum // key value from the set of vertices not yet included // in MST function minKey(keymstSet) { // Initialize min value let min = Number.MAX_VALUE min_index = 0; for (let v = 0; v < V; v++) { if (mstSet[v] == false && key[v] < min) { min = key[v]; min_index = v; } } return min_index; } // A utility function to print the constructed MST // stored in parent[] and print Minimum Obtainable // product function printMST(parentngraph) { document.write('Edge Weight
'); let minProduct = 1; for (let i = 1; i < V; i++) { document.write( parent[i]+' - '+ i+' ' +graph[i][parent[i]]+'
'); minProduct *= graph[i][parent[i]]; } document.write('Minimum Obtainable product is ' minProduct+'
'); } // Function to construct and print MST for a graph // represented using adjacency matrix representation // inputGraph is sent for printing actual edges and // logGraph is sent for actual MST operations function primMST(inputGraphlogGraph) { let parent = new Array(V); // Array to store constructed MST let key = new Array(V); // Key values used to pick minimum // weight edge in cut let mstSet = new Array(V); // To represent set of vertices not // yet included in MST // Initialize all keys as INFINITE for (let i = 0; i < V; i++) { key[i] = Number.MAX_VALUE; mstSet[i] = false; } // Always include first 1st vertex in MST. key[0] = 0; // Make key 0 so that this vertex is // picked as first vertex parent[0] = -1; // First node is always root of MST // The MST will have V vertices for (let count = 0; count < V - 1; count++) { // Pick the minimum key vertex from the set of // vertices not yet included in MST let u = minKey(key mstSet); // Add the picked vertex to the MST Set mstSet[u] = true; // Update key value and parent index of the // adjacent vertices of the picked vertex. // Consider only those vertices which are not yet // included in MST for (let v = 0; v < V; v++) // logGraph[u][v] is non zero only for // adjacent vertices of m mstSet[v] is false // for vertices not yet included in MST // Update the key only if logGraph[u][v] is // smaller than key[v] { if (logGraph[u][v] > 0 && mstSet[v] == false && logGraph[u][v] < key[v]) { parent[v] = u; key[v] = logGraph[u][v]; } } } // print the constructed MST printMST(parent V inputGraph); } // Method to get minimum product spanning tree function minimumProductMST(graph) { let logGraph = new Array(V); // Constructing logGraph from original graph for (let i = 0; i < V; i++) { logGraph[i]=new Array(V); for (let j = 0; j < V; j++) { if (graph[i][j] > 0) { logGraph[i][j] = Math.log(graph[i][j]); } else { logGraph[i][j] = 0; } } } // Applying standard Prim's MST algorithm on // Log graph. primMST(graph logGraph); } // Driver code /* Let us create the following graph 2 3 (0)--(1)--(2) | / | 6| 8/ 5 |7 | / | (3)-------(4) 9 */ let graph = [ [ 0 2 0 6 0 ] [ 2 0 3 8 5 ] [ 0 3 0 0 7 ] [ 6 8 0 0 9 ] [ 0 5 7 9 0 ] ]; // Print the solution minimumProductMST(graph); // This code is contributed by rag2127 </script>
výstup:
Edge Weight 0 - 1 2 1 - 2 3 0 - 3 6 1 - 4 5 Minimum Obtainable product is 180
The časovou složitost tohoto algoritmu je O(V2), protože existují dvě vnořené smyčky for, které iterují přes všechny vrcholy.
The prostorová složitost tohoto algoritmu je O(V2), protože k uložení vstupního grafu používáme 2D pole o velikosti V x V.