s_phys_pkgs/text/gridalt.tex

\subsection{Gridalt - Alternate Grid Package}
\label{sec:pkg:gridalt}
\begin{rawhtml}
<!-- CMIREDIR:package_gridalt: -->
\end{rawhtml}

\subsubsection {Introduction} 

The gridalt package \citep{mol:09} 
is designed to allow different components of MITgcm to
be run using horizontal and/or vertical grids which are different from the main 
model grid. The gridalt routines handle the definition of the all the various
alternative grid(s) and the mappings between them and the MITgcm grid.
The implementation of the gridalt package which allows the high end atmospheric 
physics (fizhi) to be run on a high resolution and quasi terrain-following vertical 
grid is documented here.  The package has also (with some user modifications) been used 
for other calculations within the GCM. 

The rationale for implementing the atmospheric physics on a high resolution vertical
grid involves the fact that the MITgcm $p^*$ (or any pressure-type) coordinate cannot 
maintain the vertical resolution near the surface as the bottom topography rises above
sea level. The vertical length scales near the ground are small and can vary 
on small time scales, and the vertical grid must be adequate to resolve them.
Many studies with both regional and global atmospheric models have demonstrated the 
improvements in the simulations when the vertical resolution near the surface is 
increased (\cite{bm:99,Inn:01,wo:98,breth:99}). Some of the benefit of increased resolution 
near the surface is realized by employing the higher resolution for the computation of the 
forcing due to turbulent and convective processes in the atmosphere.  

The parameterizations of atmospheric subgrid scale processes are all essentially
one-dimensional in nature, and the computation of the terms in the equations of
motion due to these processes can be performed for the air column over one grid point 
at a time.  The vertical grid on which these computations take place can therefore be 
entirely independant of the grid on which the equations of motion are integrated, and 
the 'tendency' terms can be interpolated to the vertical grid on which the equations
of motion are integrated. A modified $p^*$ coordinate, which adjusts to the local 
terrain and adds additional levels between the lower levels of the existing $p^*$ grid 
(and perhaps between the levels near the tropopause as well), is implemented. The 
vertical discretization is different for each grid point, although it consist of the 
same number of levels. Additional 'sponge' levels aloft are added when needed. The levels 
of the physics grid are constrained to fit exactly into the existing $p^*$ grid, simplifying 
the mapping between the two vertical coordinates.  This is illustrated as follows:

\begin{figure}[htbp]
\vspace*{-0.4in}
\begin{center}
\includegraphics[height=2.4in]{s_phys_pkgs/figs/vertical.eps}
\caption{Vertical discretization for MITgcm (dark grey lines) and for the
atmospheric physics (light grey lines). In this implementation, all MITgcm level
interfaces must coincide with atmospheric physics level interfaces.}
\end{center}
\end{figure}

The algorithm presented here retains the state variables on the high resolution 'physics'
grid as well as on the coarser resolution 'dynamics` grid, and ensures that the two 
estimates of the state 'agree' on the coarse resolution grid.  It would have been possible 
to implement a technique in which the tendencies due to atmospheric physics are computed 
on the high resolution grid and the state variables are retained at low resolution only. 
This, however, for the case of the turbulence parameterization,  would mean that the 
turbulent kinetic energy source terms, and all the turbulence terms that are written 
in terms of gradients of the mean flow, cannot really be computed making use of the fine 
structure in the vertical. 

\subsubsection{Equations on Both Grids}

In addition to computing the physical forcing terms of the momentum, thermodynamic and humidity 
equations on the modified (higher resolution) grid, the higher resolution structure of the 
atmosphere (the boundary layer) is retained between physics calculations. This neccessitates
a second set of evolution equations for the atmospheric state variables on the modified grid. 
If the equation for the evolution of $U$ on $p^*$ can be expressed as:
\[
\left . {\partial U \over {\partial t}} \right |_{p^*}^{total} = 
\left . {\partial U \over {\partial t}} \right |_{p^*}^{dynamics} + 
\left . {\partial U \over {\partial t}} \right |_{p^*}^{physics}
\]
where the physics forcing terms on $p^*$ have been mapped from the modified grid, then an additional 
equation to govern the evolution of $U$ (for example) on the modified grid is written:
\[
\left . {\partial U \over {\partial t}} \right |_{p^{*m}}^{total} = 
\left . {\partial U \over {\partial t}} \right |_{p^{*m}}^{dynamics} + 
\left . {\partial U \over {\partial t}} \right |_{p^{*m}}^{physics} +
\gamma ({\left . U \right |_{p^*}} - {\left . U \right |_{p^{*m}}})
\]
where $p^{*m}$ refers to the modified higher resolution grid, and the dynamics forcing terms have 
been mapped from $p^*$ space.  The last term on the RHS is a relaxation term, meant to constrain
the state variables on the modified vertical grid to `track' the state variables on the $p^*$ grid 
on some time scale, governed by $\gamma$. In the present implementation, $\gamma = 1$, requiring
an immediate agreement between the two 'states'.

\subsubsection{Time stepping Sequence}
If we write $T_{phys}$ as the temperature (or any other state variable) on the high
resolution physics grid, and $T_{dyn}$ as the temperature on the coarse vertical resolution
dynamics grid, then:

\begin{enumerate}
%\itemsep{-0.05in}

\item{Compute the tendency due to physics processes.}

\item{Advance the physics state: ${{T^{n+1}}^{**}}_{phys}(l) = {T^n}_{phys}(l) + \delta T_{phys}$.}

\item{Interpolate the physics tendency to the dynamics grid, and advance the dynamics
state by physics and dynamics tendencies:
${T^{n+1}}_{dyn}(L) = {T^n}_{dyn}(L) + \delta T_{dyn}(L) + [\delta T _{phys}(l)](L)$.}

\item{Interpolate the dynamics tendency to the physics grid, and update the physics
grid due to dynamics tendencies: 
${{T^{n+1}}^*}_{phys}(l)$ = ${{T^{n+1}}^{**}}_{phys}(l) + {\delta T_{dyn}(L)}(l)$.}

\item{Apply correction term to physics state to account for divergence from dynamics state:
${T^{n+1}}_{phys}(l)$ = ${{T^{n+1}}^*}_{phys}(l) + \gamma \{  T_{dyn}(L) - [T_{phys}(l)](L) \}(l)$.} \\
Where $\gamma=1$ here. 

\end{enumerate}

\subsubsection{Interpolation}
In order to minimize the correction terms for the state variables on the alternative,
higher resolution grid, the vertical interpolation scheme must be constructed so that
a dynamics-to-physics interpolation can be exactly reversed with a physics-to-dynamics mapping.
The simple scheme employed to achieve this is:\\

Coarse to fine:\
For all physics layers l in dynamics layer L, $ T_{phys}(l) = \{T_{dyn}(L)\} = T_{dyn}(L) $.

Fine to coarse:\
For all physics layers l in dynamics layer L, $T_{dyn}(L) = [T_{phys}(l)] = \int{T_{phys} dp } $.\\

Where $\{\}$ is defined as the dynamics-to-physics operator and $[ ]$ is the physics-to-dynamics operator, $T$ stands for any state variable, and the subscripts $phys$ and $dyn$ stand for variables on
the physics and dynamics grids, respectively.

\subsubsection {Key subroutines, parameters and files } 

\noindent
One of the central elements of the gridalt package is the routine which 
is called from subroutine gridalt\_initialise to define the grid to be
used for the high end physics calculations. Routine make\_phys\_grid
passes back the parameters which define the grid, ultimately stored 
in the common block gridalt\_mapping.

\begin{verbatim}
       subroutine make_phys_grid(drF,hfacC,im1,im2,jm1,jm2,Nr,
     . Nsx,Nsy,i1,i2,j1,j2,bi,bj,Nrphys,Lbot,dpphys,numlevphys,nlperdyn)
c***********************************************************************
c Purpose: Define the grid that the will be used to run the high-end
c          atmospheric physics.
c
c Algorithm: Fit additional levels of some (~) known thickness in
c          between existing levels of the grid used for the dynamics
c
c Need:    Information about the dynamics grid vertical spacing
c
c Input:   drF         - delta r (p*) edge-to-edge
c          hfacC       - fraction of grid box above topography
c          im1, im2    - beginning and ending i - dimensions
c          jm1, jm2    - beginning and ending j - dimensions
c          Nr          - number of levels in dynamics grid
c          Nsx,Nsy     - number of processes in x and y direction
c          i1, i2      - beginning and ending i - index to fill
c          j1, j2      - beginning and ending j - index to fill
c          bi, bj      - x-dir and y-dir index of process
c          Nrphys      - number of levels in physics grid
c
c Output:  dpphys      - delta r (p*) edge-to-edge of physics grid
c          numlevphys  - number of levels used in the physics
c          nlperdyn    - physics level number atop each dynamics layer
c
c NOTES: 1) Pressure levs are built up from bottom, using p0, ps and dp:
c              p(i,j,k)=p(i,j,k-1) + dp(k)*ps(i,j)/p0(i,j)
c        2) Output dp's are aligned to fit EXACTLY between existing
c           levels of the dynamics vertical grid
c        3) IMPORTANT! This routine assumes the levels are numbered
c           from the bottom up, ie, level 1 is the surface.
c           IT WILL NOT WORK OTHERWISE!!!
c        4) This routine does NOT work for surface pressures less
c           (ie, above in the atmosphere) than about 350 mb
c***********************************************************************
\end{verbatim}

\noindent In the case of the grid used to compute the atmospheric physical
forcing (fizhi package), the locations of the grid points move in time with 
the MITgcm $p^*$ coordinate, and subroutine gridalt\_update is called during 
the run to update the locations of the grid points:

\begin{verbatim}
       subroutine gridalt_update(myThid)
c***********************************************************************
c Purpose: Update the pressure thicknesses of the layers of the
c          alternative vertical grid (used now for atmospheric physics).
c
c Calculate: dpphys    - new delta r (p*) edge-to-edge of physics grid
c                        using dpphys0 (initial value) and rstarfacC
c***********************************************************************
\end{verbatim}

\noindent The gridalt package also supplies utility routines which perform
the mappings from one grid to the other. These routines are called from the 
code which computes the fields on the alternative (fizhi) grid.

\begin{verbatim}
      subroutine dyn2phys(qdyn,pedyn,im1,im2,jm1,jm2,lmdyn,Nsx,Nsy,
     . idim1,idim2,jdim1,jdim2,bi,bj,windphy,pephy,Lbot,lmphy,nlperdyn,
     . flg,qphy)
C***********************************************************************
C Purpose:
C   To interpolate an arbitrary quantity from the 'dynamics' eta (pstar)
C               grid to the higher resolution physics grid
C Algorithm:
C   Routine works one layer (edge to edge pressure) at a time.
C   Dynamics -> Physics retains the dynamics layer mean value,
C   weights the field either with the profile of the physics grid
C   wind speed (for U and V fields), or uniformly (T and Q)
C
C Input:
C   qdyn..... [im,jm,lmdyn] Arbitrary Quantity on Input Grid
C   pedyn.... [im,jm,lmdyn+1] Pressures at bottom edges of input levels
C   im1,2 ... Limits for Longitude Dimension of Input
C   jm1,2 ... Limits for Latitude  Dimension of Input
C   lmdyn.... Vertical  Dimension of Input
C   Nsx...... Number of processes in x-direction
C   Nsy...... Number of processes in y-direction
C   idim1,2.. Beginning and ending i-values to calculate
C   jdim1,2.. Beginning and ending j-values to calculate
C   bi....... Index of process number in x-direction
C   bj....... Index of process number in x-direction
C   windphy.. [im,jm,lmphy] Magnitude of the wind on the output levels
C   pephy.... [im,jm,lmphy+1] Pressures at bottom edges of output levels
C   lmphy.... Vertical  Dimension of Output
C   nlperdyn. [im,jm,lmdyn] Highest Physics level in each dynamics level
C   flg...... Flag to indicate field type (0 for T or Q, 1 for U or V)
C
C Output:
C   qphy..... [im,jm,lmphy] Quantity at output grid (physics grid)
C
C Notes:
C   1) This algorithm assumes that the output (physics) grid levels
C      fit exactly into the input (dynamics) grid levels
C***********************************************************************
\end{verbatim}

\noindent And similarly, gridalt contains subroutine phys2dyn.

\subsubsection {Gridalt Diagnostics}
\label{sec:pkg:gridalt:diagnostics}

{\footnotesize
\begin{verbatim}

------------------------------------------------------------------------
<-Name->|Levs|<-parsing code->|<--  Units   -->|<- Tile (max=80c) 
------------------------------------------------------------------------
DPPHYS  | 20 |SM      ML      |Pascal          |Pressure Thickness of Layers on Fizhi Grid
\end{verbatim}
}

\subsubsection {Dos and donts}

\subsubsection {Gridalt Reference} 

\subsubsection{Experiments and tutorials that use gridalt}
\label{sec:pkg:gridalt:experiments}

\begin{itemize}
\item{Fizhi experiment, in fizhi-cs-32x32x10 verification directory }
\end{itemize}
1	molod	1.4	\subsection{Gridalt - Alternate Grid Package}
2	edhill	1.2	\label{sec:pkg:gridalt}
3			\begin{rawhtml}
4			<!-- CMIREDIR:package_gridalt: -->
5			\end{rawhtml}
6	molod	1.1
7	molod	1.4	\subsubsection {Introduction}
8	molod	1.1
9	jmc	1.12	The gridalt package \citep{mol:09}
10			is designed to allow different components of MITgcm to
11	molod	1.5	be run using horizontal and/or vertical grids which are different from the main
12			model grid. The gridalt routines handle the definition of the all the various
13			alternative grid(s) and the mappings between them and the MITgcm grid.
14			The implementation of the gridalt package which allows the high end atmospheric
15			physics (fizhi) to be run on a high resolution and quasi terrain-following vertical
16			grid is documented here. The package has also (with some user modifications) been used
17			for other calculations within the GCM.
18
19			The rationale for implementing the atmospheric physics on a high resolution vertical
20			grid involves the fact that the MITgcm $p^*$ (or any pressure-type) coordinate cannot
21			maintain the vertical resolution near the surface as the bottom topography rises above
22			sea level. The vertical length scales near the ground are small and can vary
23			on small time scales, and the vertical grid must be adequate to resolve them.
24			Many studies with both regional and global atmospheric models have demonstrated the
25			improvements in the simulations when the vertical resolution near the surface is
26			increased (\cite{bm:99,Inn:01,wo:98,breth:99}). Some of the benefit of increased resolution
27			near the surface is realized by employing the higher resolution for the computation of the
28			forcing due to turbulent and convective processes in the atmosphere.
29
30			The parameterizations of atmospheric subgrid scale processes are all essentially
31			one-dimensional in nature, and the computation of the terms in the equations of
32			motion due to these processes can be performed for the air column over one grid point
33			at a time. The vertical grid on which these computations take place can therefore be
34			entirely independant of the grid on which the equations of motion are integrated, and
35			the 'tendency' terms can be interpolated to the vertical grid on which the equations
36			of motion are integrated. A modified $p^*$ coordinate, which adjusts to the local
37			terrain and adds additional levels between the lower levels of the existing $p^*$ grid
38			(and perhaps between the levels near the tropopause as well), is implemented. The
39			vertical discretization is different for each grid point, although it consist of the
40			same number of levels. Additional 'sponge' levels aloft are added when needed. The levels
41			of the physics grid are constrained to fit exactly into the existing $p^*$ grid, simplifying
42			the mapping between the two vertical coordinates. This is illustrated as follows:
43
44	molod	1.1	\begin{figure}[htbp]
45			\vspace*{-0.4in}
46			\begin{center}
47	jmc	1.13	\includegraphics[height=2.4in]{s_phys_pkgs/figs/vertical.eps}
48	edhill	1.8	\caption{Vertical discretization for MITgcm (dark grey lines) and for the
49	molod	1.5	atmospheric physics (light grey lines). In this implementation, all MITgcm level
50			interfaces must coincide with atmospheric physics level interfaces.}
51	molod	1.1	\end{center}
52			\end{figure}
53
54	molod	1.5	The algorithm presented here retains the state variables on the high resolution 'physics'
55			grid as well as on the coarser resolution 'dynamics` grid, and ensures that the two
56			estimates of the state 'agree' on the coarse resolution grid. It would have been possible
57			to implement a technique in which the tendencies due to atmospheric physics are computed
58			on the high resolution grid and the state variables are retained at low resolution only.
59			This, however, for the case of the turbulence parameterization, would mean that the
60			turbulent kinetic energy source terms, and all the turbulence terms that are written
61			in terms of gradients of the mean flow, cannot really be computed making use of the fine
62			structure in the vertical.
63
64			\subsubsection{Equations on Both Grids}
65
66			In addition to computing the physical forcing terms of the momentum, thermodynamic and humidity
67			equations on the modified (higher resolution) grid, the higher resolution structure of the
68			atmosphere (the boundary layer) is retained between physics calculations. This neccessitates
69			a second set of evolution equations for the atmospheric state variables on the modified grid.
70			If the equation for the evolution of $U$ on $p^*$ can be expressed as:
71	molod	1.1	\[
72			\left . {\partial U \over {\partial t}} \right \|_{p^*}^{total} =
73			\left . {\partial U \over {\partial t}} \right \|_{p^*}^{dynamics} +
74			\left . {\partial U \over {\partial t}} \right \|_{p^*}^{physics}
75			\]
76	molod	1.5	where the physics forcing terms on $p^*$ have been mapped from the modified grid, then an additional
77			equation to govern the evolution of $U$ (for example) on the modified grid is written:
78	molod	1.1	\[
79			\left . {\partial U \over {\partial t}} \right \|_{p^{*m}}^{total} =
80			\left . {\partial U \over {\partial t}} \right \|_{p^{*m}}^{dynamics} +
81			\left . {\partial U \over {\partial t}} \right \|_{p^{*m}}^{physics} +
82			\gamma ({\left . U \right \|_{p^}} - {\left . U \right \|_{p^{m}}})
83			\]
84	molod	1.5	where $p^{*m}$ refers to the modified higher resolution grid, and the dynamics forcing terms have
85			been mapped from $p^*$ space. The last term on the RHS is a relaxation term, meant to constrain
86			the state variables on the modified vertical grid to `track' the state variables on the $p^*$ grid
87			on some time scale, governed by $\gamma$. In the present implementation, $\gamma = 1$, requiring
88			an immediate agreement between the two 'states'.
89
90			\subsubsection{Time stepping Sequence}
91			If we write $T_{phys}$ as the temperature (or any other state variable) on the high
92			resolution physics grid, and $T_{dyn}$ as the temperature on the coarse vertical resolution
93			dynamics grid, then:
94
95			\begin{enumerate}
96			%\itemsep{-0.05in}
97
98			\item{Compute the tendency due to physics processes.}
99
100	molod	1.6	\item{Advance the physics state: ${{T^{n+1}}^{**}}_{phys}(l) = {T^n}_{phys}(l) + \delta T_{phys}$.}
101	molod	1.5
102			\item{Interpolate the physics tendency to the dynamics grid, and advance the dynamics
103			state by physics and dynamics tendencies:
104			${T^{n+1}}_{dyn}(L) = {T^n}_{dyn}(L) + \delta T_{dyn}(L) + [\delta T _{phys}(l)](L)$.}
105
106			\item{Interpolate the dynamics tendency to the physics grid, and update the physics
107			grid due to dynamics tendencies:
108	molod	1.6	${{T^{n+1}}^}_{phys}(l)$ = ${{T^{n+1}}^{*}}_{phys}(l) + {\delta T_{dyn}(L)}(l)$.}
109	molod	1.5
110			\item{Apply correction term to physics state to account for divergence from dynamics state:
111	molod	1.6	${T^{n+1}}_{phys}(l)$ = ${{T^{n+1}}^*}_{phys}(l) + \gamma \{ T_{dyn}(L) - [T_{phys}(l)](L) \}(l)$.} \\
112	molod	1.5	Where $\gamma=1$ here.
113
114			\end{enumerate}
115
116			\subsubsection{Interpolation}
117			In order to minimize the correction terms for the state variables on the alternative,
118			higher resolution grid, the vertical interpolation scheme must be constructed so that
119			a dynamics-to-physics interpolation can be exactly reversed with a physics-to-dynamics mapping.
120	molod	1.7	The simple scheme employed to achieve this is:\\
121	molod	1.5
122			Coarse to fine:\
123			For all physics layers l in dynamics layer L, $ T_{phys}(l) = \{T_{dyn}(L)\} = T_{dyn}(L) $.
124
125			Fine to coarse:\
126	molod	1.7	For all physics layers l in dynamics layer L, $T_{dyn}(L) = [T_{phys}(l)] = \int{T_{phys} dp } $.\\
127	molod	1.5
128			Where $\{\}$ is defined as the dynamics-to-physics operator and $[ ]$ is the physics-to-dynamics operator, $T$ stands for any state variable, and the subscripts $phys$ and $dyn$ stand for variables on
129			the physics and dynamics grids, respectively.
130	molod	1.1
131	molod	1.4	\subsubsection {Key subroutines, parameters and files }
132	molod	1.1
133	molod	1.7	\noindent
134			One of the central elements of the gridalt package is the routine which
135			is called from subroutine gridalt\_initialise to define the grid to be
136			used for the high end physics calculations. Routine make\_phys\_grid
137			passes back the parameters which define the grid, ultimately stored
138			in the common block gridalt\_mapping.
139
140			\begin{verbatim}
141			subroutine make_phys_grid(drF,hfacC,im1,im2,jm1,jm2,Nr,
142			. Nsx,Nsy,i1,i2,j1,j2,bi,bj,Nrphys,Lbot,dpphys,numlevphys,nlperdyn)
143			c***********************************************************************
144			c Purpose: Define the grid that the will be used to run the high-end
145			c atmospheric physics.
146			c
147			c Algorithm: Fit additional levels of some (~) known thickness in
148			c between existing levels of the grid used for the dynamics
149			c
150			c Need: Information about the dynamics grid vertical spacing
151			c
152			c Input: drF - delta r (p*) edge-to-edge
153			c hfacC - fraction of grid box above topography
154			c im1, im2 - beginning and ending i - dimensions
155			c jm1, jm2 - beginning and ending j - dimensions
156			c Nr - number of levels in dynamics grid
157			c Nsx,Nsy - number of processes in x and y direction
158			c i1, i2 - beginning and ending i - index to fill
159			c j1, j2 - beginning and ending j - index to fill
160			c bi, bj - x-dir and y-dir index of process
161			c Nrphys - number of levels in physics grid
162			c
163			c Output: dpphys - delta r (p*) edge-to-edge of physics grid
164			c numlevphys - number of levels used in the physics
165			c nlperdyn - physics level number atop each dynamics layer
166			c
167			c NOTES: 1) Pressure levs are built up from bottom, using p0, ps and dp:
168			c p(i,j,k)=p(i,j,k-1) + dp(k)*ps(i,j)/p0(i,j)
169			c 2) Output dp's are aligned to fit EXACTLY between existing
170			c levels of the dynamics vertical grid
171			c 3) IMPORTANT! This routine assumes the levels are numbered
172			c from the bottom up, ie, level 1 is the surface.
173			c IT WILL NOT WORK OTHERWISE!!!
174			c 4) This routine does NOT work for surface pressures less
175			c (ie, above in the atmosphere) than about 350 mb
176			c***********************************************************************
177			\end{verbatim}
178
179			\noindent In the case of the grid used to compute the atmospheric physical
180			forcing (fizhi package), the locations of the grid points move in time with
181			the MITgcm $p^*$ coordinate, and subroutine gridalt\_update is called during
182			the run to update the locations of the grid points:
183
184			\begin{verbatim}
185			subroutine gridalt_update(myThid)
186			c***********************************************************************
187			c Purpose: Update the pressure thicknesses of the layers of the
188			c alternative vertical grid (used now for atmospheric physics).
189			c
190			c Calculate: dpphys - new delta r (p*) edge-to-edge of physics grid
191			c using dpphys0 (initial value) and rstarfacC
192			c***********************************************************************
193			\end{verbatim}
194
195			\noindent The gridalt package also supplies utility routines which perform
196			the mappings from one grid to the other. These routines are called from the
197			code which computes the fields on the alternative (fizhi) grid.
198
199			\begin{verbatim}
200			subroutine dyn2phys(qdyn,pedyn,im1,im2,jm1,jm2,lmdyn,Nsx,Nsy,
201			. idim1,idim2,jdim1,jdim2,bi,bj,windphy,pephy,Lbot,lmphy,nlperdyn,
202			. flg,qphy)
203			C***********************************************************************
204			C Purpose:
205			C To interpolate an arbitrary quantity from the 'dynamics' eta (pstar)
206			C grid to the higher resolution physics grid
207			C Algorithm:
208			C Routine works one layer (edge to edge pressure) at a time.
209			C Dynamics -> Physics retains the dynamics layer mean value,
210			C weights the field either with the profile of the physics grid
211			C wind speed (for U and V fields), or uniformly (T and Q)
212			C
213			C Input:
214			C qdyn..... [im,jm,lmdyn] Arbitrary Quantity on Input Grid
215			C pedyn.... [im,jm,lmdyn+1] Pressures at bottom edges of input levels
216			C im1,2 ... Limits for Longitude Dimension of Input
217			C jm1,2 ... Limits for Latitude Dimension of Input
218			C lmdyn.... Vertical Dimension of Input
219			C Nsx...... Number of processes in x-direction
220			C Nsy...... Number of processes in y-direction
221			C idim1,2.. Beginning and ending i-values to calculate
222			C jdim1,2.. Beginning and ending j-values to calculate
223			C bi....... Index of process number in x-direction
224			C bj....... Index of process number in x-direction
225			C windphy.. [im,jm,lmphy] Magnitude of the wind on the output levels
226			C pephy.... [im,jm,lmphy+1] Pressures at bottom edges of output levels
227			C lmphy.... Vertical Dimension of Output
228			C nlperdyn. [im,jm,lmdyn] Highest Physics level in each dynamics level
229			C flg...... Flag to indicate field type (0 for T or Q, 1 for U or V)
230			C
231			C Output:
232			C qphy..... [im,jm,lmphy] Quantity at output grid (physics grid)
233			C
234			C Notes:
235			C 1) This algorithm assumes that the output (physics) grid levels
236			C fit exactly into the input (dynamics) grid levels
237			C***********************************************************************
238			\end{verbatim}
239
240			\noindent And similarly, gridalt contains subroutine phys2dyn.
241
242	molod	1.9	\subsubsection {Gridalt Diagnostics}
243			\label{sec:pkg:gridalt:diagnostics}
244
245	edhill	1.10	{\footnotesize
246	molod	1.9	\begin{verbatim}
247
248			------------------------------------------------------------------------
249			<-Name->\|Levs\|<-parsing code->\|<-- Units -->\|<- Tile (max=80c)
250			------------------------------------------------------------------------
251			DPPHYS \| 20 \|SM ML \|Pascal \|Pressure Thickness of Layers on Fizhi Grid
252			\end{verbatim}
253	edhill	1.10	}
254	molod	1.9
255	molod	1.4	\subsubsection {Dos and donts}
256	molod	1.1
257	molod	1.4	\subsubsection {Gridalt Reference}
258	molod	1.11
259			\subsubsection{Experiments and tutorials that use gridalt}
260			\label{sec:pkg:gridalt:experiments}
261
262			\begin{itemize}
263			\item{Fizhi experiment, in fizhi-cs-32x32x10 verification directory }
264			\end{itemize}