In Part A of the present study, subtitled 'The Consumption Function as Solution of a Boundary Value Problem' Discussion Paper No. TE/96/297, STICERD, London School of Economics, we formulated a Brownian model of accumulation and derived sufficient conditions for optimality of a plan generated by a logarithmic consumption function, i.e. a relation expressing log-consumption as a time-invariant, deterministic function H(z) of log-capital z (both variables being measured in 'intensive' units). Writing h(z) = H'(z), J(z) = exp{H(z)-z}, the conditions require that the pair (h,J) satisfy a certain non-linear, non-autonomous (but asymptotically autonomous) system of o.d.e.s (F,G) of the form h'(z) = F(h,J,z), J'(z) = G(h,J) = (h-1)J for real z, and that h(z) and J(z) converge to certain limiting values (depending on parameters) as z tends to + or - infinity. The present paper, which is self-contained mathematically, analyses this system and shows that the resulting two-point boundary value problem has a (unique) solution for each range of parameter values considered. This solution may be characterised as the connection between saddle points of the autonomous systems obtained from (F,G) as z tends to + or - infinity.