2

Suppose that A, B, and C are decision problems. Suppose also that A is polynomial-time reducible to B and that B is polynomial-time reducible to C. If both A and C are NP-complete, then does it imply that B is also NP-complete?

I know that, if A is NP-complete and it is polynomial-time reducible to B, then B is NP-hard. However, in order for a problem to be NP-complete, it must meet (1) it's in NP, and (2) it's NP-hard.

I have no idea how to prove the first requirement of NP-complete.

closed as off-topic by user1864610, Portland Runner, Makoto, UmNyobe, HugoRune Feb 27 '14 at 17:17

  • This question does not appear to be about programming within the scope defined in the help center.
If this question can be reworded to fit the rules in the help center, please edit the question.

5

If A is NP-complete and it is polynomial time reducible to B, then B is NP-hard.

If B is polynomial time reducible to C and C is NP-complete, then B is in NP.

A problem in NP which is in NP-hard is NP-complete.

Another way to show B is NP-complete is to notice that any two NP-complete problems (e.g A and C) are polynomially reducible to each other, and thus B is equivalent (two-way polynomially reducible) to any NP-complete problem.

-1
Les try Out:- (REC= Recursive lang, REL=Recursive Enumerable lang, UD= Undecidable, D= Decidable)  

if P < Q than

  UD-->UD

  D<--D

  P<--P

  P,NP<--NP

  NPC-->NPH

  P,NP--> we can't anything it may be (NP,NPH,REC,REL)

  REC<-- REC

  REL<--REL

  D--> Can't say anything.

   ?<--UD


we know that P is Proper Subset of NP. (as P != Np)

and All NPC is NPH.

to prove NPC:-
""
if NP reducible to X problem than that X is NPH.

if X reducible to any NPC than that X is NPC.""

p^NPC=0

Not the answer you're looking for? Browse other questions tagged or ask your own question.