| ... | ... | @@ -916,7 +916,7 @@ Here is an example of looping over the active region of a superblock: |
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The tracer array index, `ic`, runs from 0 to `_C.tracer`-1 whereas the
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species array index, `is`, runs from 0 to `_C.species`-1. Tracer
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variables are assumed dimensionless and it are usually defined in the
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range $[0,1]$. The mesh of the superblock is indexed by
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range [0,1]. The mesh of the superblock is indexed by
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(`ix`,`iy`,`iz`).
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**Important:** The species number densities must be consistently defined
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| ... | ... | @@ -1110,7 +1110,7 @@ The macro `SPQR(a,b,c)` defined in header file `nirvana.h` shortcuts the |
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algebraic expression $a^2+b^2+c^2$.
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**Example 2** (taken from `/nirvana/testproblems/MHD/problem17`; cf.
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[@Z05])
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[Z05](#references))
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IC for the shock-cloud interaction problem simulated in a 3D Cartesian
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box given by $(x,y,z)\in [-1/2,1/2]^3$:
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| ... | ... | @@ -1118,7 +1118,7 @@ $$(\varrho,p,v_x,v_y,v_z,B_x,B_y,B_z)=\left\{\begin{array}{ll} |
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(3.86859,167.345,0,0,0,0,2.1826182,-2.1826182) & x<0.1\\
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(1,1,-11.2536,0,0,0,0.56418958,0.56418958) & x\ge 0.1
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\end{array}\right.$$ At ${\mathbf x}=(0.3,0,0)$ a spherical clump with
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radius $0.15$ and density of $10$ is embedded and co-moving with its
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radius 0.15 and density of 10 is embedded and co-moving with its
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surrounding flow under the assumption of pressure equilibrium. The
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adiabatic index $\gamma =5/3$ and magnetic permeability $\mu=1$. The
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grid is initially refined with 3 refinement levels, `_C.level`=3, in the
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| ... | ... | @@ -1254,8 +1254,8 @@ boundary. |
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#### User-defined BC
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When U specified BC at the corresponding domain boundary are assumed
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user-defined. In that case the code calls user-programmable functions in
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With letter U boundary conditions at the corresponding domain boundary
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is assumed user-specified. In that case the code calls user-programmable functions in
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the following modules:
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| module | function | BC for |
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| ... | ... | @@ -1282,7 +1282,7 @@ formalism is enabled (cf. [Specification of main simulation |
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parameters](#specification-of-main-simulation-parameters)).
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Boundary values have to be assigned in ghost cells running from to
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`g->ixs`-1 ( to `g->iys`-1, to `g->izs`-1) in $x$($y$,$z$)-direction at
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`g->ixs`-1 ( to `g->iys`-1, to `g->izs`-1) in x(y,z)-direction at
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the lower domain boundary. At upper domain boundaries the index range
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depends on the type of variable as listed in the following table:
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| ... | ... | @@ -1305,7 +1305,7 @@ is adopted to transform MHD BC types into BC types for $\Phi$: |
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| M,A,R | | von-Neumann |
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| I,O,D | | Dirichlet |
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| F | | not supported |
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| U | | user-defined *Φ* (function `phiUser()` |
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| U | | user-defined *Φ* (function `phiUser()`)|
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In case of von-Neumann conditions (M,A,R) the gradient of potential
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vanishes normal to the corresponding domain boundary, i.e.,
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