Table 1.

Notation used in the single locus process model.

Parameter	Definition
A	Number of alleles
S	Number of populations in each geographical region
k	Number of geographical regions
P	Total number of populations. P = kS
V	An A × A matrix of mutation rates. v _rs is the mutation rate from the rth allele to the sth allele
M	A P × P matrix of backward migration rates. m _ij is the probability that an allele in population i came from population j in the preceding generation
B	The Kronecker product of M and V
N _ij	Number of individuals in population j of geographical region i
$p_{ij}^{(t)}$	The vector of allele frequencies in population j of geographical region i at time t. $p_{ij, r}^{(t)}$ is the frequency of the rth allele.
Properties when the process has reached stationarity.
u_ij	The mean vector of allele frequencies in population j of geographical region i.
Σ_ij,ij	The variance-covariance of allele frequencies within population j of geographical region i.
Σ_ij,i′j′	The covariance of allele frequencies between population j of geographical region i and popogulation j′ of geographical region i′.
Finite island model
m ₀	Probability that an allele came from the same population in the preceding generation.
m ₁	Probability that an allele came from a different population in the same geographical region in the preceding generation.
m ₂	Probability that an allele came from a different geographical region in the preceding generation.
F-statistics
$F_{S T} = \frac{σ_{p}^{2}}{μ_{p} (1 - μ_{p})}$	Wright's F _ST, where $σ_{p}^{2}$ is the variance of allele frequencies and μ_p is the mean allele frequency.
θ	An interpretation of F _ST that arises when μ_p is taken as the mean allele frequency and $σ_{p}^{2}$ is taken as the allele frequency variance in a single population over time.
$θ (p_{11}^{(t)}, \dots, p_{kS}^{(t)})$	An interpretation of F _ST that arises when μ_p is taken as the mean allele frequency and $σ_{p}^{2}$ is taken as the allele frequency variance across populations at a single time.