show/hide this revision's text 3 oops, I think I meant "seminal", not "seminar"

Cook's Theorem

The class NP can be defined as the class of problems decidable by a nondeterministic Turing machine in polynomial time. This theorem shows that SAT is NP-complete by encoding the operation of any nondeterministic Turing machine by a boolean formula, in such a way that the machine accepts if and only if that formula is SATisfiable.

Historically speaking, the notion of NP-completeness was introduced in Richard Karp's seminar seminal paper (Reducibility Among Combinatorial Problems), where he defined NP-completeness, used Cook's Theoremtheorem, and in one big shot, proved 21 problems NP-complete.
show/hide this revision's text 2 making sure it isn't missed :)

Cook's Theorem

The class NP can be defined as the class of problems decidable by a nondeterministic Turing machine in polynomial time. This theorem shows that SAT is NP-complete by encoding the operation of any nondeterministic Turing machine by a boolean formula, in such a way that the machine accepts if and only if that formula is SATisfiable.

Historically speaking, the notion of NP-completeness was introduced in Richard Karp's seminar paper (Reducibility Among Combinatorial Problems), where he defined NP-completeness, used Cook's Theorem, and in one big shot, proved 21 problems NP-complete.
show/hide this revision's text 1

Cook's Theorem

The class NP can be defined as the class of problems decidable by a nondeterministic Turing machine in polynomial time. This theorem shows that SAT is NP-complete by encoding the operation of any nondeterministic Turing machine by a boolean formula, in such a way that the machine accepts if and only if that formula is SATisfiable.

Historically speaking, the notion of NP-completeness was introduced in Richard Karp's seminar paper (Reducibility Among Combinatorial Problems), where he defined NP-completeness, used Cook's Theorem, and in one big shot, proved 21 problems NP-complete.