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Cook’s theorem and NP-reductions

Pasi Fränti. Cook’s theorem and NP-reductions. 6.11.2016. Cook’s theorem. Theorem: Satisfiability problem (SAT) is NP-complete Proof:. TM ≤ p SAT. Satisfiability problem. f 1. f 2. f 3. F=(X 1  X 2  X 3 )  ( X 1  X 2 )  ( X 1  X 3 ). Non-deterministic algorithm.

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Cook’s theorem and NP-reductions

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  1. Pasi Fränti Cook’s theorem and NP-reductions 6.11.2016

  2. Cook’s theorem Theorem: Satisfiability problem (SAT) is NP-complete Proof: TM ≤p SAT

  3. Satisfiability problem f1 f2 f3 F=(X1 X2  X3)  (X1 X2)(X1 X3)

  4. Non-deterministic algorithm Satisfiability(F) FOR i1 TO n DO xi  Choose{0,1}; IF F(x)=1 THEN SUCCESS; ELSE FAIL; T(n)=O(n)  SAT  NP

  5. Notations needed Implication Equivalence All are true Some is true Exactly one is true At least oneis true At most one is true

  6. Proof of Cook’s theorem Only valid Turing machine configurations can have value TRUE ai = tape position s has symbol ai qj = machine is at state qj and R/W head is at position s

  7. Cook’s theorem Machine is at state q0 Tape content is {ai1, ai2, …, ain}

  8. Cook’s theorem If not at position s, then content does not change If at position sand content is ai, then change state and content

  9. Cook’s theorem Can be in any position s but machine must be in final state qk

  10. NP hard problems • Satisfiability problem (SAT) • Coloring problem (Color) • Exact cover problem (EC) • Knapsack problem (KP) • Traveling salesman problem (TSP)

  11. c1 c2 c3 … ck x1 x2 x3 … xk x1 … xj xk x3 x2 Satisfiability to Coloring Complete k-clique False color c0 Connect to all but ci Literals Color for fi xj fi fi Connect to all but those literals in fi

  12. SP to Coloring example (X1 X2)  (X1 X3)

  13. Additional example f1 f2 f3 (X2 X3)  (X1 X3 )  (X1 X2)

  14. Knapsack to TSP

  15. Knapsack problem • Input: knapsack instance {2,3,5,7,11} • Size of the knapsack S=15.

  16. Step 1: Create one node for every item • Input: knapsack instance {2,3,5,7,11} • Create a node for every knapsack element. 2 7 5 3 11

  17. Step 2: Add start and end points • Add node 0 as the home. • Add node n+1 as the turning point. 2 7 5 0 n+1 3 11 n+2 nodes needed to represent the knapsack instance

  18. Step 3: Create forward links • Draw links from smaller to bigger with weights: • w(i,j) = j • w(i,n+1) = 0 7 2 2 7 7 7 7 0 5 0 5 0 5 0 n+1 0 5 0 11 11 3 11 3 3 11 11

  19. Step 4: Create backward links • Draw backward links from bigger to smaller nodes. • Set weight of the link as w(j,i)=0. 0 2 7 0 0 0 0 0 0 0 0 0 5 0 0 n+1 0 0 0 0 0 0 3 11 0

  20. All nodes have two incoming links with weights w(i,j) if item j is taken into knapsack (xj=1) 0 if item jnot is taken (xj=0) Visit nodes selected in KP using w>0 link 2 7 5 3 11 KP  TSP 0 select 7 0 0 0 n+1 5 select select 0 3

  21. 2 7 5 3 11 KP  TSP TSP = 0-3-5-7-(N+1)-11-2-0  KP = {3,5,7} (all nodes which arrival cost > 0) 0 select 7 0 0 0 n+1 5 select select 0 3

  22. Empty space for notes

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