We recall that the seeing FWHM angle is an integral
function of the temperature structure coefficient 
which in turn
can be defined in terms of the two
dissipation quantities 
(momentum) and 
(temperature) - see equation (
) at page .
If a k-
scheme is used in the model the dissipation
rate 
and the eddy diffusivities 
and 
are readily
available in the program output.
One can then compute numerically
the temperature dissipation 
at any node by computing
numerically its definition over the model grid:
Thus 
can be evaluated
at each node of the model and integrated according to ()
to obtain the FWHM angle.
This general procedure is summarized in fig. below.
Figure: General procedure for evaluating seeing from a CFD model
One such model has been developed under an ESO contract by the Risø National Laboratory (Denmark) with the purpose of computing theoretical seeing profile through the atmospheric surface layer in mountain terrain [de Baas]. The outcome of this work outlined some problems associated with the use of CFD models for seeing evaluation:
More recently a simulation aiming at predicting seeing through the entire atmosphere was attempted at Meteo-France by means of the mesoscale numerical weather prediction model PERIDOT [Bourgeault]. The model was quite comprehensive in incorporating accurate representations of radiative and friction transfer and of turbulence in general, being used operatively for meteorologic predictions. A favorable comparisons of model output and seeing measurements is reported, although some reserves on the effective usefulness of the results were expressed because the model low resolution (respectively 10 km and 3 km in the two cases studied).