The probability of finding theith species and particle at the scalel is defined
aspi¼Ni/N, whereNis the total number of species or particles andNiis theith
species and particle at scalel. This probability,pi, is used to compute the
partition function (Evertsz & Mandelbrot, 1992 ) as:qðlÞ¼XNðlÞ
i¼ 1pqil
ðqÞ ( 8 : 7 )where
(q) is the Re ́nyi or mass exponent ofq-moments, which is given as:
ðqÞ¼limlogqðlÞ
logl( 8 : 8 )Moments of order q act as a scanning tool scrutinizing the denser and
sparser regions of the measure(Chhabra & Jensen, 1989 ). Whenq>0,empha-
sizes regions in the distribution with higher proportions (concentrations) of the
measure, whereas the opposite is true forq<0. More generally, theq-moments
are linked to the dynamics of the scale-related distributions and measure the
amount of non-additivity in the system (Keylock, 2005 ).
It follows that Re ́nyi’s generalized dimension,Dq, which is based on the
concept of generalized entropies (Re ́nyi, 1955 ), is given as:DqðlÞ¼1
1 qllim!1logqðlÞ
logl ¼
ðqÞ
ð 1 qÞ forq6¼^1 (^8 :^9 )forq¼1,D 1 ðlÞ¼llim!1NPðlÞ
i¼ 1pilogpi
logl ¼d
ðqÞ
dq (^8 :^10 )and forq¼ 0D 0 ðlÞ¼lim
l!1logNðlÞ
logl( 8 : 11 )whereD 0 is the capacity,D 1 the entropy andD 2 the correlation dimension.D 0 is
equivalent to the single fractal dimension of the measure,D 1 is the entropy
dimension and quantifies the degree of disorder present in the distribution, and
D 2 is mathematically linked to the correlation function, estimating the correla-
tion of measures contained in intervals of sizel.Asqvaries from1toþ1,
the functionDqdescribes the spectrum of generalized fractal dimensions. One
can theoretically encounter difficulties in establishing reliable estimates ofDq
forq>0, because positiveq-moments diminish the terms with smallerpiand the
limit converges very slowly (Schroeder, 1991 ). To overcome this potential draw-
back, the numerator in Eq. (8.9) was calculated for bothl and 2l following the
procedure outlined in Halseyet al.(1986).154 P.E. SCHMID AND J. M. SCHMID-ARAYA