We consider a new hierarchy of semidefinite relaxations for the general polynomial optimization problem $$(P):\,f^{*}=\min \{f(x):x\in K\}$$ ( P ) : f ∗ = min { f ( x ) : x ∈ K } on a compact basic semi-algebraic set $$K\subset \mathbb {R}^n$$ K ⊂ R n . This hierarchy combines some advantages of the standard LP-relaxations associated with Krivine’s positivity certificate and some advantages of the standard SOS-hierarchy. In particular it has the following attractive features: (a) in contrast to the standard SOS-hierarchy, for each relaxation in the hierarchy, the size of the matrix associated with the semidefinite constraint is the same and fixed in advance by the user; (b) in contrast to the LP-hierarchy, finite convergence occurs at the first step of the hierarchy for an important class of convex problems; and (c) some important techniques related to the use of point evaluations for declaring a polynomial to be zero and to the use of rank-one matrices make an efficient implementation possible. Preliminary results on a sample of non convex problems are encouraging.