Correlation function for generalized P\'olya urns: Finite-size scaling analysis

Abstract

We describe a universality class of the transitions of a generalized P\'olya urn by studying the asymptotic behavior of the normalized correlation function C(t) using finite-size scaling analysis. X(1),X(2),·s are the successive additions of a red (blue) ball [X(t)=1\,(0)] at stage t and C(t) Cov(X(1),X(t+1))/Var(X(1)). Furthermore, z(t)=Σs=1tX(s)/t represents the successive proportions of red balls in an urn to which, at the t+1-th stage, a red ball is added, [X(t+1)=1], with probability q(z(t))=( [J(2z(t)-1)+h]+1)/2,J 0, and a blue ball is added, [X(t)=0], with probability 1-q(z(t)). A boundary (Jc(h),h) exists in the (J,h) plane between a region with one fixed point and another region with two stable fixed points for q(z). C(t) c+a· tl-1 with c=0\,(>0) for J<Jc\,(J>Jc), and l is the (larger) value of the slope(s) of q(z) at the stable fixed point(s). On the boundary J=Jc(h), C(t) c+a· (t)-α' and c=0\,(c>0), α'=0.5\,(1.0) for h=0\,(h≠ 0). The system shows a continuous phase transition for h=0 and C(t) behaves as C(t) t-α'g((1-l) t) with an universal function g(x) and a length scale 1/(1-l) with respect to t. β=||· α' holds with critical exponent β=1/2 and ||=1.