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Chapter 5 Dynamic Programming 2001 년 5 월 24 일 충북대학교 알고리즘연구실
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Dynamic Programming Used when the solution of a problem is a result of a sequence of decisions Example –Knapsack –Shortest path –Optimal merge patterns
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5.3 All pairs shortest paths G(V,E) : A directed graph with n vertices A k (i,j) : Length of shortest path from i to j going through no vertex of index greater than k A(i,j) = min{min{A k-1 (i,k) + A k-1 (k,j)},cost(i,j)} A k (i,j) = A k-1 (i,k) + A k-1 (k,j) A k (i,j) = min{A k-1 (i,j),A k-1 (i,k) + A k-1 (k,j)},k>=1 C(i,j) = 0, 1<=i<=n C(i,j) Cost of edge if (i,j) E if i j and (i,j) E
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5.3 All pairs shortest paths Figure 5.5 Graph with negative cycle 123 11 -2
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5.3 All pairs shortest paths Program 5.3 Function to compute lengths of shortest paths
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5.3 All pairs shortest paths Figure 5.6 Directed Graph and associated matrices
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5.4 Single-source shortest paths: General weights dist[u] = cost[v][u] dist l [u] = length of a shortest path from the source vertex V to vertex U under the constraint that the shortest path contains at most L edges 순환관계 –dist k [u] = min(dist k-1 [u],min(dist k-1 [i] + cost[i][u])),2<=k<=n-1
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5.4 Single-source shortest paths: General weights Figure 5.10 Shortest paths with negative edge lengths
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5.4 Single-source shortest paths: General weights Program 5.4 Bellman and Ford algorithm to compute shortest paths
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5.5 Optimal binary search trees Definition –A binary search tree T All identifies in the T left < T root All identifies in the T right < T root The left and right subtres of T are also BST 가정 –a 1 < a 2 < … < a n –T i,j : OBST for a i+1, …,a j –C i,j : cost for T i,j –R i,j : root of T i,j –Weight of T i,j : W i,j = Q i +
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5.5 Optimal binary search trees P(i) : probability Search(a(i)) Q(i) : probability search (a(i) < x < a(i+1)) : Probability of an unsuccessful search Internal node External node (5.9)
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Optimal Binary Search Tree Cost of the search Tree p(k)+cost(l)+cost(r)+w(0,k-1)+w(k,n) c(0, n) = min{c(0, k-1) + c(k, n) +p(k) +w(0, k-1)+w(k, n)} c(i, j) = min{c(i, k-1), c(k, j)+p(k) + w(i,k-1)+w(k,j)} C(i,j) = min{c(i,k-1)+c(k,j)} + w(i,j)
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5.5 Optimal binary search trees Figure 5.12 Two possible binary search trees
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5.5 Optimal binary search trees Figure 5.13 Binary search trees of Figure 5.12 with external nodes added
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5.5 Optimal binary search trees
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Figure 5.16 Computation of c(0,4), w(0,4), and r(0,4)
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5.8 Reliability design Solve a problem with a multiplicative optimization function Several devices are connected in series r i be the reliability of device D i Reliability of the entire system Duplicate : multiple copies of the same device type are connected in parallel use switching circuits
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5.8 Reliability design Figure 5.19 n devices D i, 1<=i<=n, connected in series Figure 5.20 Multiple devices connected in parallel in each stage
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Multiple copies stage in contain m i copies of D i P(all m i malfunction) = (1-r i ) mi Reliability of stage i =1-(1-r i ) mi
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5.8 Reliability design Maximum allowable cost of the system Maximize Subject to M i >=1 and integer, 1<=i<=n Assume c i >0 u i =
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5.9 The traveling salesperson problem 우체부 : n 개의 틀린 장소에서 mail pickup –n+1 vertex graph –Edge distance from i to j –Tour of minimum cost Permutation problem –n! different permutation of n object while there are 2 n different subset of n object n! > O(2 n )
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5.9 The traveling salesperson problem Tour : simple path that starts and ends at vertex 1 Every tour : edge for some k v-{1} each Optimal tour : path(k,1) –Shortest k to 1 path all the vertices in V-{1,k} Let g(i,s) be the length of a shortest path starting at vertex i, going through all vertices in S and terminating at vertex 1
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5.9 The traveling salesperson problem Figure 5.21 Directed graph and edge length matrix c
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5.9 The traveling salesperson problem Thus g(2, ) = c 21 = 5, g(3, ) = c 31 = 6, and g(4, ) = c 41 = 8. We obtain g(2,{3}) = c 23 + g(3, ) = 15 g(2,{4}) = 18 g(3,{2}) = 18 g(3,{4}) = 20 g(4,{2}) = 13 g(4,{3}) = 15 g(2,{3,4}) = min{c 23 +g(3,{4}),c 24 +g(4,{3})} = 25 g(3,{2,4}) = min{c 32 +g(2,{4}),c 34 +g(4,{2})} = 25 g(4,{2,3}) = min{c 42 +g(2,{3}),c 43 +g(3,{2})} = 23 g(1,{2,3,4}) = min{c 12 +g(2,{3,4}),c 13 +g(3,{2,4}),c 14 +g(4,{2,3})} = min(35,40,43} = 35
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5.9 The traveling salesperson problem Let N be the number of g(i,s), that have to be computed before g(1,V-{1}) i, computed for each value of |s| n-1 choices of i The number of distinct sets of S of size k not including 1 and i
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