Variables
integer, save	nvar = 0
	number of solved variables (must be lower than nvarmx) More...

integer, save	nscal = 0
	number of solved user scalars effective number of scalars solutions of an advection equation, apart from the variables of the turbulence model ( , $\varepsilon$ , $R_{ij}$ , $\omega$ , $\varphi$ , $\overline{f}$ , $\alpha$ , $\nu_T$ ), that is to say the temperature and other scalars (passive or not, user-defined or not) These scalars can be divided into two distinct groups: nscaus user-defined scalars and nscapp scalars related to a "specific physics". nscal=nscaus+nscapp, and nscal must be inferior or equal to nscamx. More...

integer, save	ndimfb
	fake dimension for some boundary face arrays where nfabor = 0 (to avoid issues with array bounds when multidimensional arrays have size nfabor in one dimension) More...

Detailed Description

Variable Documentation

◆ ndimfb

integer, save ndimfb

fake dimension for some boundary face arrays where nfabor = 0 (to avoid issues with array bounds when multidimensional arrays have size nfabor in one dimension)

◆ nscal

integer, save nscal = 0

number of solved user scalars effective number of scalars solutions of an advection equation, apart from the variables of the turbulence model ( , $\varepsilon$ , $R_{ij}$ , $\omega$ , $\varphi$ , $\overline{f}$ , $\alpha$ , $\nu_T$ ), that is to say the temperature and other scalars (passive or not, user-defined or not) These scalars can be divided into two distinct groups: nscaus user-defined scalars and nscapp scalars related to a "specific physics". nscal=nscaus+nscapp, and nscal must be inferior or equal to nscamx.

◆ nvar

integer, save nvar = 0

number of solved variables (must be lower than nvarmx)

Variables

Detailed Description

Variable Documentation

◆ ndimfb

◆ nscal

◆ nvar