Bibcode
DOI
Atanackovic-Vukmanovic, O.; Crivellari, L.; Simonneau, E.
Referencia bibliográfica
Astrophysical Journal v.487, p.735
Fecha de publicación:
10
1997
Número de citas
12
Número de citas referidas
9
Descripción
In many radiative transfer (RT) problems, the sources contain a
scattering term that couples all the specific RT equations, one for each
frequency and direction, so that solving the problem means solving the
system formed by these equations. Each of them is a first-order linear
differential equation with its own initial condition assigned at a
different point of the medium, which makes the solution of the system
extraordinarily difficult. One simple way to achieve a solution is with
the so-called Lamda -iteration: sources and sinks given as a first
approximation --> computation of the specific intensities from their
own RT equations --> computation of the scattering terms -->
recomputation of the sources and sinks. This scheme is straightforward,
but unfortunately in practice its convergence rate is too slow to be of
value in the case of optically thick systems. The aim of this paper is
to show that a forth-and-back approach (the natural approach to
describing sequentially the two intensities propagating along the two
directions of a straight line), together with an implicit representation
of the source function in the computation of the intensities within the
above iterative scheme, can dramatically accelerate the convergence of
the iterative process while retaining the straightforwardness of
ordinary Lamda -iteration.