/[MITgcm]/manual/s_algorithm/text/time_stepping.tex

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-revision 1.3 by jmc,
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+revision 1.15 by cnh,
Thu Feb 28 19:32:19 2002 UTC
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  % $Header$
  % $Name$
- The convention used in this section is as follows:
+ This chapter lays out the numerical schemes that are
- Time is "discretize" using a time step $\Delta t$
+ employed in the core MITgcm algorithm. Whenever possible
- and $\Phi^n$ refers to the variable $\Phi$
+ links are made to actual program code in the MITgcm implementation.
- at time $t = n \Delta t$ . We used the notation $\Phi^{(n)}$
+ The chapter begins with a discussion of the temporal discretization
- when time interpolation is required to estimate the value of $\phi$
+ used in MITgcm. This discussion is followed by sections that
- at the time $n \Delta t$.
+ describe the spatial discretization. The schemes employed for momentum
+ terms are described first, afterwards the schemes that apply to
- \section{Time integration}
+ passive and dynamically active tracers are described.
- The discretization in time of the model equations (cf section I )
- does not depend of the discretization in space of each
+ \section{Time-stepping}
- term, so that this section can be read independently.
+ The equations of motion integrated by the model involve four
- Also for this purpose, we will refers to the continuous
+ prognostic equations for flow, $u$ and $v$, temperature, $\theta$, and
- space-derivative form of model equations, and focus on
+ salt/moisture, $S$, and three diagnostic equations for vertical flow,
- the time discretization.
+ $w$, density/buoyancy, $\rho$/$b$, and pressure/geo-potential,
+ $\phi_{hyd}$. In addition, the surface pressure or height may by
- The continuous form of the model equations is:
+ described by either a prognostic or diagnostic equation and if
+ non-hydrostatics terms are included then a diagnostic equation for
- \begin{eqnarray}
+ non-hydrostatic pressure is also solved. The combination of prognostic
- \partial_t \theta & = & G_\theta
+ and diagnostic equations requires a model algorithm that can march
- \\
+ forward prognostic variables while satisfying constraints imposed by
- \partial_t S & = & G_s
+ diagnostic equations.
- \\
- b' & = & b'(\theta,S,r)
+ Since the model comes in several flavors and formulation, it would be
- \\
+ confusing to present the model algorithm exactly as written into code
- \partial_r \phi'_{hyd} & = & -b'
+ along with all the switches and optional terms. Instead, we present
- \label{eq-r-split-hyd}
+ the algorithm for each of the basic formulations which are:
- \\
+ \begin{enumerate}
- \partial_t \vec{\bf v}
+ \item the semi-implicit pressure method for hydrostatic equations
- + {\bf \nabla}_h b_s \eta
+ with a rigid-lid, variables co-located in time and with
- + \epsilon_{nh} {\bf \nabla}_h \phi'_{nh}
+ Adams-Bashforth time-stepping, \label{it:a}
- & = & \vec{\bf G}_{\vec{\bf v}}
+ \item as \ref{it:a}. but with an implicit linear free-surface, \label{it:b}
- - {\bf \nabla}_h \phi'_{hyd}
+ \item as \ref{it:a}. or \ref{it:b}. but with variables staggered in time,
- \label{eq-r-split-hmom}
+ \label{it:c}
- \\
+ \item as \ref{it:a}. or \ref{it:b}. but with non-hydrostatic terms included,
- \epsilon_{nh} \frac {\partial{\dot{r}}}{\partial{t}}
+ \item as \ref{it:b}. or \ref{it:c}. but with non-linear free-surface.
- + \epsilon_{nh} \partial_r \phi'_{nh}
+ \end{enumerate}
- & = & \epsilon_{nh} G_{\dot{r}}
- \label{eq-r-split-rdot}
+ In all the above configurations it is also possible to substitute the
- \\
+ Adams-Bashforth with an alternative time-stepping scheme for terms
- {\bf \nabla}_h \cdot \vec{\bf v} + \partial_r \dot{r}
+ evaluated explicitly in time. Since the over-arching algorithm is
- & = & 0
+ independent of the particular time-stepping scheme chosen we will
- \label{eq-r-cont}
+ describe first the over-arching algorithm, known as the pressure
+ method, with a rigid-lid model in section
+ \ref{sect:pressure-method-rigid-lid}. This algorithm is essentially
+ unchanged, apart for some coefficients, when the rigid lid assumption
+ is replaced with a linearized implicit free-surface, described in
+ section \ref{sect:pressure-method-linear-backward}. These two flavors
+ of the pressure-method encompass all formulations of the model as it
+ exists today. The integration of explicit in time terms is out-lined
+ in section \ref{sect:adams-bashforth} and put into the context of the
+ overall algorithm in sections \ref{sect:adams-bashforth-sync} and
+ \ref{sect:adams-bashforth-staggered}. Inclusion of non-hydrostatic
+ terms requires applying the pressure method in three dimensions
+ instead of two and this algorithm modification is described in section
+ \ref{sect:non-hydrostatic}. Finally, the free-surface equation may be
+ treated more exactly, including non-linear terms, and this is
+ described in section \ref{sect:nonlinear-freesurface}.
+ \section{Pressure method with rigid-lid} \label{sect:pressure-method-rigid-lid}
+ \begin{figure}
+ \begin{center}
+ \resizebox{4.0in}{!}{\includegraphics{part2/pressure-method-rigid-lid.eps}}
+ \end{center}
+ \caption{
+ A schematic of the evolution in time of the pressure method
+ algorithm. A prediction for the flow variables at time level $n+1$ is
+ made based only on the explicit terms, $G^{(n+^1/_2)}$, and denoted
+ $u^*$, $v^*$. Next, a pressure field is found such that $u^{n+1}$,
+ $v^{n+1}$ will be non-divergent. Conceptually, the $*$ quantities
+ exist at time level $n+1$ but they are intermediate and only
+ temporary.}
+ \label{fig:pressure-method-rigid-lid}
+ \end{figure}
+ \begin{figure}
+ \begin{center} \fbox{ \begin{minipage}{4.5in} \begin{tabbing}
+ aaa \= aaa \= aaa \= aaa \= aaa \= aaa \kill
+ \proclink{FORWARD\_STEP}{../code/._model_src_forward_step.F} \\
+ \> DYNAMICS \\
+ \>\> TIMESTEP \` $u^*$,$v^*$ (\ref{eq:ustar-rigid-lid},\ref{eq:vstar-rigid-lid}) \\
+ \> SOLVE\_FOR\_PRESSURE \\
+ \>\> CALC\_DIV\_GHAT \` $H\widehat{u^*}$,$H\widehat{v^*}$ (\ref{eq:elliptic}) \\
+ \>\> CG2D \` $\eta^{n+1}$ (\ref{eq:elliptic}) \\
+ \> THE\_CORRECTION\_STEP  \\
+ \>\> CALC\_GRAD\_PHI\_SURF \` $\nabla \eta^{n+1}$ \\
+ \>\> CORRECTION\_STEP \` $u^{n+1}$,$v^{n+1}$ (\ref{eq:un+1-rigid-lid},\ref{eq:vn+1-rigid-lid})
+ \end{tabbing} \end{minipage} } \end{center}
+ \caption{Calling tree for the pressure method algorihtm}
+ \label{fig:call-tree-pressure-method}
+ \end{figure}
+ The horizontal momentum and continuity equations for the ocean
+ (\ref{eq:ocean-mom} and \ref{eq:ocean-cont}), or for the atmosphere
+ (\ref{eq:atmos-mom} and \ref{eq:atmos-cont}), can be summarized by:
+ \begin{eqnarray}
+ \partial_t u + g \partial_x \eta & = & G_u \\
+ \partial_t v + g \partial_y \eta & = & G_v \\
+ \partial_x u + \partial_y v + \partial_z w & = & 0
  \end{eqnarray}
- where
+ where we are adopting the oceanic notation for brevity. All terms in
- \begin{eqnarray*}
+ the momentum equations, except for surface pressure gradient, are
- G_\theta & = &
+ encapsulated in the $G$ vector. The continuity equation, when
- - \vec{\bf v} \cdot {\bf \nabla} \theta + {\cal Q}_\theta
+ integrated over the fluid depth, $H$, and with the rigid-lid/no normal
- \\
+ flow boundary conditions applied, becomes:
- G_S & = &
+ \begin{equation}
- - \vec{\bf v} \cdot {\bf \nabla} S + {\cal Q}_S
+ \partial_x H \widehat{u} + \partial_y H \widehat{v} = 0
- \\
+ \label{eq:rigid-lid-continuity}
- \vec{\bf G}_{\vec{\bf v}}
+ \end{equation}
+ Here, $H\widehat{u} = \int_H u dz$ is the depth integral of $u$,
+ similarly for $H\widehat{v}$. The rigid-lid approximation sets $w=0$
+ at the lid so that it does not move but allows a pressure to be
+ exerted on the fluid by the lid. The horizontal momentum equations and
+ vertically integrated continuity equation are be discretized in time
+ and space as follows:
+ \begin{eqnarray}
+ u^{n+1} + \Delta t g \partial_x \eta^{n+1}
+ & = & u^{n} + \Delta t G_u^{(n+1/2)}
+ \label{eq:discrete-time-u}
+ \\
+ v^{n+1} + \Delta t g \partial_y \eta^{n+1}
+ & = & v^{n} + \Delta t G_v^{(n+1/2)}
+ \label{eq:discrete-time-v}
+ \\
+   \partial_x H \widehat{u^{n+1}}
+ + \partial_y H \widehat{v^{n+1}} & = & 0
+ \label{eq:discrete-time-cont-rigid-lid}
+ \end{eqnarray}
+ As written here, terms on the LHS all involve time level $n+1$ and are
+ referred to as implicit; the implicit backward time stepping scheme is
+ being used. All other terms in the RHS are explicit in time. The
+ thermodynamic quantities are integrated forward in time in parallel
+ with the flow and will be discussed later. For the purposes of
+ describing the pressure method it suffices to say that the hydrostatic
+ pressure gradient is explicit and so can be included in the vector
+ $G$.
+ Substituting the two momentum equations into the depth integrated
+ continuity equation eliminates $u^{n+1}$ and $v^{n+1}$ yielding an
+ elliptic equation for $\eta^{n+1}$. Equations
+ \ref{eq:discrete-time-u}, \ref{eq:discrete-time-v} and
+ \ref{eq:discrete-time-cont-rigid-lid} can then be re-arranged as follows:
+ \begin{eqnarray}
+ u^{*} & = & u^{n} + \Delta t G_u^{(n+1/2)} \label{eq:ustar-rigid-lid} \\
+ v^{*} & = & v^{n} + \Delta t G_v^{(n+1/2)} \label{eq:vstar-rigid-lid} \\
+   \partial_x \Delta t g H \partial_x \eta^{n+1}
+ + \partial_y \Delta t g H \partial_y \eta^{n+1}
  & = &
- - \vec{\bf v} \cdot {\bf \nabla} \vec{\bf v}
+   \partial_x H \widehat{u^{*}}
- - f \hat{\bf k} \wedge \vec{\bf v}
+ + \partial_y H \widehat{v^{*}} \label{eq:elliptic}
- + \vec{\cal F}_{\vec{\bf v}}
  \\
- G_{\dot{r}}
+ u^{n+1} & = & u^{*} - \Delta t g \partial_x \eta^{n+1} \label{eq:un+1-rigid-lid}\\
- & = &
+ v^{n+1} & = & v^{*} - \Delta t g \partial_y \eta^{n+1} \label{eq:vn+1-rigid-lid}
- - \vec{\bf v} \cdot {\bf \nabla} \dot{r}
+ \end{eqnarray}
- + {\cal F}_{\dot{r}}
+ Equations \ref{eq:ustar-rigid-lid} to \ref{eq:vn+1-rigid-lid}, solved
- \end{eqnarray*}
+ sequentially, represent the pressure method algorithm used in the
- The exact form of all the "{\it G}"s terms is described in the next
+ model. The essence of the pressure method lies in the fact that any
- section (). Here its sufficient to mention that they contains
+ explicit prediction for the flow would lead to a divergence flow field
- all the RHS terms except the pressure / geo- potential terms.
+ so a pressure field must be found that keeps the flow non-divergent
+ over each step of the integration. The particular location in time of
- The switch $\epsilon_{nh}$ allows to activate the non hydrostatic
+ the pressure field is somewhat ambiguous; in
- mode ($\epsilon_{nh}=1$) for the ocean model. Otherwise,
+ Fig.~\ref{fig:pressure-method-rigid-lid} we depicted as co-located
- in the hydrostatic limit $\epsilon_{nh} = 0$
+ with the future flow field (time level $n+1$) but it could equally
- and equation \ref{eq-r-split-rdot} vanishes.
+ have been drawn as staggered in time with the flow.
- The equation for $\eta$ is obtained by integrating the
+ The correspondence to the code is as follows:
- continuity equation over the entire depth of the fluid,
+ \begin{itemize}
- from $R_{min}(x,y)$ up to $R_o(x,y)$
+ \item
- (Linear free surface):
+ the prognostic phase, equations \ref{eq:ustar-rigid-lid} and \ref{eq:vstar-rigid-lid},
- \begin{eqnarray}
+ stepping forward $u^n$ and $v^n$ to $u^{*}$ and $v^{*}$ is coded in
- \epsilon_{fs} \partial_t \eta =
+ \proclink{TIMESTEP}{../code/._model_src_timestep.F}
- \left. \dot{r} \right|_{r=r_{surf}} + \epsilon_{fw} (P-E) =
+ \item
- - {\bf \nabla} \cdot \int_{R_{min}}^{R_o} \vec{\bf v} dr
+ the vertical integration, $H \widehat{u^*}$ and $H
- + \epsilon_{fw} (P-E)
+ \widehat{v^*}$, divergence and inversion of the elliptic operator in
- \label{eq-cont-2D}
+ equation \ref{eq:elliptic} is coded in
- \end{eqnarray}
+ \proclink{SOLVE\_FOR\_PRESSURE}{../code/._model_src_solve_for_pressure.F}
+ \item
- Where $\epsilon_{fs}$,$\epsilon_{fw}$ are two flags to
+ finally, the new flow field at time level $n+1$ given by equations
- distinguish between a free-surface equation ($\epsilon_{fs}=1$)
+ \ref{eq:un+1-rigid-lid} and \ref{eq:vn+1-rigid-lid} is calculated in
- or the rigid-lid approximation ($\epsilon_{fs}=0$);
+ \proclink{CORRECTION\_STEP}{../code/._model_src_correction_step.F}.
- and to distinguish when exchange of Fresh-Water is included
+ \end{itemize}
- at the ocean surface (natural BC) ($\epsilon_{fw} = 1$)
+ The calling tree for these routines is given in
- or not ($\epsilon_{fw} = 0$).
+ Fig.~\ref{fig:call-tree-pressure-method}.
- The hydrostatic potential is found by
- integrating \ref{eq-r-split-hyd} with the boundary condition that
- $\phi'_{hyd}(r=R_o) = 0$:
- \begin{eqnarray*}
- & &
- \int_{r'}^{R_o} \partial_r \phi'_{hyd} dr =
- \left[ \phi'_{hyd} \right]_{r'}^{R_o} =
- \int_{r'}^{R_o} - b' dr
- \\
- \Rightarrow & &
- \phi'_{hyd}(x,y,r') = \int_{r'}^{R_o} b' dr
- \end{eqnarray*}
- \subsection{General method}
- The general algorithm consist in  a "predictor step" that computes
+ \paragraph{Need to discuss implicit viscosity somewhere:}
- the forward tendencies ("G" terms") and all
+ \begin{eqnarray}
- the "first guess" values star notation):
+ \frac{1}{\Delta t} u^{n+1} - \partial_z A_v \partial_z u^{n+1}
- $\vec{\bf v}^*, \theta^*, S^*$ (and $\dot{r}^*$
+ + g \partial_x \eta^{n+1} & = & \frac{1}{\Delta t} u^{n} +
- in non-hydrostatic mode). This is done in the routine {\it DYNAMICS}.
+ G_u^{(n+1/2)}
- Then the implicit terms that appear here on the left hand side (LHS),
- are solved as follows:
- Since implicit vertical diffusion and viscosity terms
- are independent from the barotropic flow adjustment,
- they are computed first, solving a 3 diagonal Nr x Nr linear system,
- and incorporated at the end of the {\it DYNAMICS} routines.
- Then the surface pressure and non hydrostatic pressure
- are evaluated ({\it SOLVE\_FOR\_PRESSURE});
- Finally, within a "corrector step',
- (routine {\it THE\_CORRECTION\_STEP})
- the new values of $u,v,w,\theta,S$
- are derived according to the above equations
- (see details in II.1.3).
- At this point, the regular time step is over, but
- the correction step contains also other optional
- adjustments such as convective adjustment algorithm, or filters
- (zonal FFT filter, shapiro filter)
- that applied on both momentum and tracer fields.
- just before setting the $n+1$ new time step value.
- Since the pressure solver precision is of the order of
- the "target residual" that could be lower than the
- the computer truncation error, and also because some filters
- might alter the divergence part of the flow field,
- a final evaluation of the surface r anomaly $\eta^{n+1}$
- is performed, according to \ref{eq-rtd-eta} ({\it CALC\_EXACT\_ETA}).
- This ensures a perfect volume conservation.
- Note that there is no need for an equivalent Non-hydrostatic
- "exact conservation" step, since W is already computed after
- the filters applied.
- optionnal forcing terms (package):\\
- Regarding optional forcing terms (usually part of a "package"),
- that a account for a specific source or sink term (e.g.: condensation
- as a sink of water vapor Q), they are generally incorporated
- in the main algorithm as follows;
- At the the beginning of the time step,
- the additionnal tendencies are computed
- as function of the present state (time step $n$) and external forcing ;
- Then within the main part of model,
- only those new tendencies are added to the model variables.
- [more details needed]\\
- The atmospheric physics follows this general scheme.
- \subsection{Standard synchronous time stepping}
- In the standard formulation, the surface pressure is
- evaluated at time step n+1 (implicit method).
- The above set of equations is then discretized in time
- as follows:
- \begin{eqnarray}
- \left[ 1 - \partial_r \kappa_v^\theta \partial_r \right]
- \theta^{n+1} & = & \theta^*
- \\
- \left[ 1 - \partial_r \kappa_v^S \partial_r \right]
- S^{n+1} & = & S^*
- \\
- %{b'}^{n} & = & b'(\theta^{n},S^{n},r)
- %\partial_r {\phi'_{hyd}}^{n} & = & {-b'}^{n}
- %\\
- {\phi'_{hyd}}^{n} & = & \int_{r'}^{R_o} b'(\theta^{n},S^{n},r) dr
- \label{eq-rtd-hyd}
- \\
- \vec{\bf v} ^{n+1}
- + \Delta t {\bf \nabla}_h b_s {\eta}^{n+1}
- + \epsilon_{nh} \Delta t {\bf \nabla} {\phi'_{nh}}^{n+1}
- - \partial_r A_v \partial_r \vec{\bf v}^{n+1}
- & = &
- \vec{\bf v}^*
- \label{eq-rtd-hmom}
  \\
- \epsilon_{fs} {\eta}^{n+1} + \Delta t
+ \frac{1}{\Delta t} v^{n+1} - \partial_z A_v \partial_z v^{n+1}
- {\bf \nabla}_h \cdot \int_{R_{min}}^{R_o} \vec{\bf v}^{n+1} dr
+ + g \partial_y \eta^{n+1} & = & \frac{1}{\Delta t} v^{n} + G_v^{(n+1/2)}
- & = &
-     \epsilon_{fs} {\eta}^{n} + \epsilon_{fw} \Delta_t (P-E)^{n}
- \nonumber
- \\
- % = \epsilon_{fs} {\eta}^{n} & + & \epsilon_{fw} \Delta_t (P-E)^{n}
- \label{eq-rtd-eta}
- \\
- \epsilon_{nh} \left( \dot{r} ^{n+1}
- + \Delta t \partial_r {\phi'_{nh}} ^{n+1}
- \right)
- & = & \epsilon_{nh} \dot{r}^*
- \label{eq-rtd-rdot}
- \\
- {\bf \nabla}_h \cdot \vec{\bf v}^{n+1} + \partial_r \dot{r}^{n+1}
- & = & 0
- \label{eq-rtd-cont}
  \end{eqnarray}
- where
+ \section{Pressure method with implicit linear free-surface}
+ \label{sect:pressure-method-linear-backward}
+ The rigid-lid approximation filters out external gravity waves
+ subsequently modifying the dispersion relation of barotropic Rossby
+ waves. The discrete form of the elliptic equation has some zero
+ eigen-values which makes it a potentially tricky or inefficient
+ problem to solve.
+ The rigid-lid approximation can be easily replaced by a linearization
+ of the free-surface equation which can be written:
+ \begin{equation}
+ \partial_t \eta + \partial_x H \widehat{u} + \partial_y H \widehat{v} = P-E+R
+ \label{eq:linear-free-surface=P-E+R}
+ \end{equation}
+ which differs from the depth integrated continuity equation with
+ rigid-lid (\ref{eq:rigid-lid-continuity}) by the time-dependent term
+ and fresh-water source term.
+ Equation \ref{eq:discrete-time-cont-rigid-lid} in the rigid-lid
+ pressure method is then replaced by the time discretization of
+ \ref{eq:linear-free-surface=P-E+R} which is:
+ \begin{equation}
+ \eta^{n+1}
+ + \Delta t \partial_x H \widehat{u^{n+1}}
+ + \Delta t \partial_y H \widehat{v^{n+1}}
+ =
+ \eta^{n}
+ + \Delta t ( P - E + R )
+ \label{eq:discrete-time-backward-free-surface}
+ \end{equation}
+ where the use of flow at time level $n+1$ makes the method implicit
+ and backward in time. The is the preferred scheme since it still
+ filters the fast unresolved wave motions by damping them. A centered
+ scheme, such as Crank-Nicholson, would alias the energy of the fast
+ modes onto slower modes of motion.
+ As for the rigid-lid pressure method, equations
+ \ref{eq:discrete-time-u}, \ref{eq:discrete-time-v} and
+ \ref{eq:discrete-time-backward-free-surface} can be re-arranged as follows:
  \begin{eqnarray}
- \theta^* & = &
+ u^{*} & = & u^{n} + \Delta t G_u^{(n+1/2)} \label{eq:ustar-backward-free-surface} \\
- \theta ^{n} + \Delta t G_{\theta} ^{(n+1/2)}
+ v^{*} & = & v^{n} + \Delta t G_v^{(n+1/2)} \label{eq:vstar-backward-free-surface} \\
- \\
+ \eta^* & = & \epsilon_{fs} \left( \eta^{n} +P-E+R \right)- \Delta t
- S^* & = &
+   \partial_x H \widehat{u^{*}}
- S ^{n} + \Delta t G_{S} ^{(n+1/2)}
+ + \partial_y H \widehat{v^{*}}
  \\
- \vec{\bf v}^* & = &
+   \partial_x g H \partial_x \eta^{n+1}
- \vec{\bf v}^{n} + \Delta t \vec{\bf G}_{\vec{\bf v}} ^{(n+1/2)}
+ + \partial_y g H \partial_y \eta^{n+1}
- + \Delta t  {\bf \nabla}_h {\phi'_{hyd}}^{(n+1/2)}
+ - \frac{\epsilon_{fs} \eta^{n+1}}{\Delta t^2}
+ & = &
+ - \frac{\eta^*}{\Delta t^2}
+ \label{eq:elliptic-backward-free-surface}
  \\
- \dot{r}^* & = &
+ u^{n+1} & = & u^{*} - \Delta t g \partial_x \eta^{n+1} \label{eq:un+1-backward-free-surface}\\
- \dot{r} ^{n} + \Delta t G_{\dot{r}} ^{(n+1/2)}
+ v^{n+1} & = & v^{*} - \Delta t g \partial_y \eta^{n+1} \label{eq:vn+1-backward-free-surface}
  \end{eqnarray}
+ Equations~\ref{eq:ustar-backward-free-surface}
+ to~\ref{eq:vn+1-backward-free-surface}, solved sequentially, represent
+ the pressure method algorithm with a backward implicit, linearized
+ free surface. The method is still formerly a pressure method because
+ in the limit of large $\Delta t$ the rigid-lid method is
+ recovered. However, the implicit treatment of the free-surface allows
+ the flow to be divergent and for the surface pressure/elevation to
+ respond on a finite time-scale (as opposed to instantly). To recover
+ the rigid-lid formulation, we introduced a switch-like parameter,
+ $\epsilon_{fs}$, which selects between the free-surface and rigid-lid;
+ $\epsilon_{fs}=1$ allows the free-surface to evolve; $\epsilon_{fs}=0$
+ imposes the rigid-lid. The evolution in time and location of variables
+ is exactly as it was for the rigid-lid model so that
+ Fig.~\ref{fig:pressure-method-rigid-lid} is still
+ applicable. Similarly, the calling sequence, given in
+ Fig.~\ref{fig:call-tree-pressure-method}, is as for the
+ pressure-method.
+ \section{Explicit time-stepping: Adams-Bashforth}
+ \label{sect:adams-bashforth}
+ In describing the the pressure method above we deferred describing the
+ time discretization of the explicit terms. We have historically used
+ the quasi-second order Adams-Bashforth method for all explicit terms
+ in both the momentum and tracer equations. This is still the default
+ mode of operation but it is now possible to use alternate schemes for
+ tracers (see section \ref{sect:tracer-advection}).
+ \begin{figure}
+ \begin{center} \fbox{ \begin{minipage}{4.5in} \begin{tabbing}
+ aaa \= aaa \= aaa \= aaa \= aaa \= aaa \kill
+ FORWARD\_STEP \\
+ \> THERMODYNAMICS \\
+ \>\> CALC\_GT \\
+ \>\>\> GAD\_CALC\_RHS \` $G_\theta^n = G_\theta( u, \theta^n )$ \\
+ \>\>\> EXTERNAL\_FORCING \` $G_\theta^n = G_\theta^n + {\cal Q}$ \\
+ \>\>\> ADAMS\_BASHFORTH2 \` $G_\theta^{(n+1/2)}$ (\ref{eq:adams-bashforth2}) \\
+ \>\> TIMESTEP\_TRACER \` $\tau^*$ (\ref{eq:taustar}) \\
+ \>\> IMPLDIFF \` $\tau^{(n+1)}$ (\ref{eq:tau-n+1-implicit})
+ \end{tabbing} \end{minipage} } \end{center}
+ \caption{
+ Calling tree for the Adams-Bashforth time-stepping of temperature with
+ implicit diffusion.}
+ \label{fig:call-tree-adams-bashforth}
+ \end{figure}
- Note that implicit vertical terms (viscosity and diffusivity) are
+ In the previous sections, we summarized an explicit scheme as:
- not considered as part of the "{\it G}" terms, but are
+ \begin{equation}
- written separately here.
+ \tau^{*} = \tau^{n} + \Delta t G_\tau^{(n+1/2)}
+ \label{eq:taustar}
- To ensure a second order time discretization for both
+ \end{equation}
- momentum and tracer,
+ where $\tau$ could be any prognostic variable ($u$, $v$, $\theta$ or
- The "G" terms are "extrapolated" forward in time
+ $S$) and $\tau^*$ is an explicit estimate of $\tau^{n+1}$ and would be
- (Adams Bashforth time stepping)
+ exact if not for implicit-in-time terms. The parenthesis about $n+1/2$
- from the values computed at time step $n$ and $n-1$
+ indicates that the term is explicit and extrapolated forward in time
- to the time $n+1/2$:
+ and for this we use the quasi-second order Adams-Bashforth method:
- $$G^{(n+1/2)} = G^n + (1/2+\epsilon_{AB}) (G^n - G^{n-1})$$
+ \begin{equation}
- A small number for the parameter $\epsilon_{AB}$ is generally used
+ G_\tau^{(n+1/2)} = ( 3/2 + \epsilon_{AB}) G_\tau^n
- to stabilize this time stepping.
+ - ( 1/2 + \epsilon_{AB}) G_\tau^{n-1}
+ \label{eq:adams-bashforth2}
- In the standard non-stagger formulation,
+ \end{equation}
- the Adams-Bashforth time stepping is also applied to the
+ This is a linear extrapolation, forward in time, to
- hydrostatic (pressure / geo-) potential term $\nabla_h \Phi'_{hyd}$.
+ $t=(n+1/2+{\epsilon_{AB}})\Delta t$. An extrapolation to the mid-point
- Note that presently, this term is in fact incorporated to the
+ in time, $t=(n+1/2)\Delta t$, corresponding to $\epsilon_{AB}=0$,
- $\vec{\bf G}_{\vec{\bf v}}$ arrays ({\bf gU,gV}).
+ would be second order accurate but is weakly unstable for oscillatory
+ terms. A small but finite value for $\epsilon_{AB}$ stabilizes the
- \subsection{Stagger baroclinic time stepping}
+ method. Strictly speaking, damping terms such as diffusion and
+ dissipation, and fixed terms (forcing), do not need to be inside the
- An alternative is to evaluate $\phi'_{hyd}$ with the
+ Adams-Bashforth extrapolation. However, in the current code, it is
- new tracer fields, and step forward the momentum after.
+ simpler to include these terms and this can be justified if the flow
- This option is known as stagger baroclinic time stepping,
+ and forcing evolves smoothly. Problems can, and do, arise when forcing
- since tracer and momentum are step forward in time one after the other.
+ or motions are high frequency and this corresponds to a reduced
- It can be activated turning on a running flag parameter
+ stability compared to a simple forward time-stepping of such terms.
- {\bf staggerTimeStep} in file "{\it data}").
+ A stability analysis for an oscillation equation should be given at this point.
- The main advantage of this time stepping compared to a synchronous one,
+ \marginpar{AJA needs to find his notes on this...}
- is a better stability, specially regarding internal gravity waves,
- and a very natural implementation of a 2nd order in time
+ A stability analysis for a relaxation equation should be given at this point.
- hydrostatic pressure / geo- potential term.
+ \marginpar{...and for this too.}
- In the other hand, a synchronous time step might be  better
- for convection problems; Its also make simpler time dependent forcing
- and diagnostic implementation ; and allows a more efficient threading.
+ \section{Implicit time-stepping: backward method}
- Although the stagger time step does not affect deeply the
+ Vertical diffusion and viscosity can be treated implicitly in time
- structure of the code --- a switch allows to evaluate the
+ using the backward method which is an intrinsic scheme. For tracers,
- hydrostatic pressure / geo- potential from new $\theta,S$
+ the time discretized equation is:
- instead of the Adams-Bashforth estimation ---
+ \begin{equation}
- this affect the way the time discretization is presented :
+ \tau^{n+1} - \Delta t \partial_r \kappa_v \partial_r \tau^{n+1} =
+ \tau^{n} + \Delta t G_\tau^{(n+1/2)}
+ \label{eq:implicit-diffusion}
+ \end{equation}
+ where $G_\tau^{(n+1/2)}$ is the remaining explicit terms extrapolated
+ using the Adams-Bashforth method as described above.  Equation
+ \ref{eq:implicit-diffusion} can be split split into:
+ \begin{eqnarray}
+ \tau^* & = & \tau^{n} + \Delta t G_\tau^{(n+1/2)}
+ \label{eq:taustar-implicit} \\
+ \tau^{n+1} & = & {\cal L}_\tau^{-1} ( \tau^* )
+ \label{eq:tau-n+1-implicit}
+ \end{eqnarray}
+ where ${\cal L}_\tau^{-1}$ is the inverse of the operator
+ \begin{equation}
+ {\cal L} = \left[ 1 + \Delta t \partial_r \kappa_v \partial_r \right]
+ \end{equation}
+ Equation \ref{eq:taustar-implicit} looks exactly as \ref{eq:taustar}
+ while \ref{eq:tau-n+1-implicit} involves an operator or matrix
+ inversion. By re-arranging \ref{eq:implicit-diffusion} in this way we
+ have cast the method as an explicit prediction step and an implicit
+ step allowing the latter to be inserted into the over all algorithm
+ with minimal interference.
+ Fig.~\ref{fig:call-tree-adams-bashforth} shows the calling sequence for
+ stepping forward a tracer variable such as temperature.
+ In order to fit within the pressure method, the implicit viscosity
+ must not alter the barotropic flow. In other words, it can on ly
+ redistribute momentum in the vertical. The upshot of this is that
+ although vertical viscosity may be backward implicit and
+ unconditionally stable, no-slip boundary conditions may not be made
+ implicit and are thus cast as a an explicit drag term.
+ \section{Synchronous time-stepping: variables co-located in time}
+ \label{sect:adams-bashforth-sync}
+ \begin{figure}
+ \begin{center}
+ \resizebox{5.0in}{!}{\includegraphics{part2/adams-bashforth-sync.eps}}
+ \end{center}
+ \caption{
+ A schematic of the explicit Adams-Bashforth and implicit time-stepping
+ phases of the algorithm. All prognostic variables are co-located in
+ time. Explicit tendencies are evaluated at time level $n$ as a
+ function of the state at that time level (dotted arrow). The explicit
+ tendency from the previous time level, $n-1$, is used to extrapolate
+ tendencies to $n+1/2$ (dashed arrow). This extrapolated tendency
+ allows variables to be stably integrated forward-in-time to render an
+ estimate ($*$-variables) at the $n+1$ time level (solid
+ arc-arrow). The operator ${\cal L}$ formed from implicit-in-time terms
+ is solved to yield the state variables at time level $n+1$. }
+ \label{fig:adams-bashforth-sync}
+ \end{figure}
+ \begin{figure}
+ \begin{center} \fbox{ \begin{minipage}{4.5in} \begin{tabbing}
+ aaa \= aaa \= aaa \= aaa \= aaa \= aaa \kill
+ FORWARD\_STEP \\
+ \> THERMODYNAMICS \\
+ \>\> CALC\_GT \\
+ \>\>\> GAD\_CALC\_RHS \` $G_\theta^n = G_\theta( u, \theta^n )$ (\ref{eq:Gt-n-sync})\\
+ \>\>\> EXTERNAL\_FORCING \` $G_\theta^n = G_\theta^n + {\cal Q}$ \\
+ \>\>\> ADAMS\_BASHFORTH2 \` $G_\theta^{(n+1/2)}$ (\ref{eq:Gt-n+5-sync}) \\
+ \>\> TIMESTEP\_TRACER \` $\tau^*$ (\ref{eq:tstar-sync}) \\
+ \>\> IMPLDIFF \` $\tau^{(n+1)}$ (\ref{eq:t-n+1-sync}) \\
+ \> DYNAMICS \\
+ \>\> CALC\_PHI\_HYD \` $\phi_{hyd}^n$ (\ref{eq:phi-hyd-sync}) \\
+ \>\> MOM\_FLUXFORM or MOM\_VECINV \` $G_{\vec{\bf v}}^n$ (\ref{eq:Gv-n-sync})\\
+ \>\> TIMESTEP \` $\vec{\bf v}^*$ (\ref{eq:Gv-n+5-sync}, \ref{eq:vstar-sync}) \\
+ \>\> IMPLDIFF \` $\vec{\bf v}^{**}$ (\ref{eq:vstarstar-sync}) \\
+ \> SOLVE\_FOR\_PRESSURE \\
+ \>\> CALC\_DIV\_GHAT \` $\eta^*$ (\ref{eq:nstar-sync}) \\
+ \>\> CG2D \` $\eta^{n+1}$ (\ref{eq:elliptic-sync}) \\
+ \> THE\_CORRECTION\_STEP  \\
+ \>\> CALC\_GRAD\_PHI\_SURF \` $\nabla \eta^{n+1}$ \\
+ \>\> CORRECTION\_STEP \` $u^{n+1}$,$v^{n+1}$ (\ref{eq:v-n+1-sync})
+ \end{tabbing} \end{minipage} } \end{center}
+ \caption{
+ Calling tree for the overall synchronous algorithm using
+ Adams-Bashforth time-stepping.}
+ \label{fig:call-tree-adams-bashforth-sync}
+ \end{figure}
+ The Adams-Bashforth extrapolation of explicit tendencies fits neatly
+ into the pressure method algorithm when all state variables are
+ co-located in time. Fig.~\ref{fig:adams-bashforth-sync} illustrates
+ the location of variables in time and the evolution of the algorithm
+ with time. The algorithm can be represented by the sequential solution
+ of the follow equations:
+ \begin{eqnarray}
+ G_{\theta,S}^{n} & = & G_{\theta,S} ( u^n, \theta^n, S^n )
+ \label{eq:Gt-n-sync} \\
+ G_{\theta,S}^{(n+1/2)} & = & (3/2+\epsilon_{AB}) G_{\theta,S}^{n}-(1/2+\epsilon_{AB}) G_{\theta,S}^{n-1}
+ \label{eq:Gt-n+5-sync} \\
+ (\theta^*,S^*) & = & (\theta^{n},S^{n}) + \Delta t G_{\theta,S}^{(n+1/2)}
+ \label{eq:tstar-sync} \\
+ (\theta^{n+1},S^{n+1}) & = & {\cal L}^{-1}_{\theta,S} (\theta^*,S^*)
+ \label{eq:t-n+1-sync} \\
+ \phi^n_{hyd} & = & \int b(\theta^n,S^n) dr
+ \label{eq:phi-hyd-sync} \\
+ \vec{\bf G}_{\vec{\bf v}}^{n} & = & \vec{\bf G}_{\vec{\bf v}} ( \vec{\bf v}^n, \phi^n_{hyd} )
+ \label{eq:Gv-n-sync} \\
+ \vec{\bf G}_{\vec{\bf v}}^{(n+1/2)} & = & (3/2 + \epsilon_{AB} ) \vec{\bf G}_{\vec{\bf v}}^{n} - (1/2 + \epsilon_{AB} ) \vec{\bf G}_{\vec{\bf v}}^{n-1}
+ \label{eq:Gv-n+5-sync} \\
+ \vec{\bf v}^{*} & = & \vec{\bf v}^{n} + \Delta t \vec{\bf G}_{\vec{\bf v}}^{(n+1/2)}
+ \label{eq:vstar-sync} \\
+ \vec{\bf v}^{**} & = & {\cal L}_{\vec{\bf v}}^{-1} ( \vec{\bf v}^* )
+ \label{eq:vstarstar-sync} \\
+ \eta^* & = & \epsilon_{fs} \left( \eta^{n} +P-E+R \right)- \Delta t
+   \nabla \cdot H \widehat{ \vec{\bf v}^{**} }
+ \label{eq:nstar-sync} \\
+ \nabla \cdot g H \nabla \eta^{n+1} - \frac{\epsilon_{fs} \eta^{n+1}}{\Delta t^2}
+ & = & - \frac{\eta^*}{\Delta t^2}
+ \label{eq:elliptic-sync} \\
+ \vec{\bf v}^{n+1} & = & \vec{\bf v}^{*} - \Delta t g \nabla \eta^{n+1}
+ \label{eq:v-n+1-sync}
+ \end{eqnarray}
+ Fig.~\ref{fig:adams-bashforth-sync} illustrates the location of
+ variables in time and evolution of the algorithm with time. The
+ Adams-Bashforth extrapolation of the tracer tendencies is illustrated
+ by the dashed arrow, the prediction at $n+1$ is indicated by the
+ solid arc. Inversion of the implicit terms, ${\cal
+ L}^{-1}_{\theta,S}$, then yields the new tracer fields at $n+1$. All
+ these operations are carried out in subroutine {\em THERMODYNAMICS} an
+ subsidiaries, which correspond to equations \ref{eq:Gt-n-sync} to
+ \ref{eq:t-n+1-sync}.
+ Similarly illustrated is the Adams-Bashforth extrapolation of
+ accelerations, stepping forward and solving of implicit viscosity and
+ surface pressure gradient terms, corresponding to equations
+ \ref{eq:Gv-n-sync} to \ref{eq:v-n+1-sync}.
+ These operations are carried out in subroutines {\em DYNAMCIS}, {\em
+ SOLVE\_FOR\_PRESSURE} and {\em THE\_CORRECTION\_STEP}. This, then,
+ represents an entire algorithm for stepping forward the model one
+ time-step. The corresponding calling tree is given in
+ \ref{fig:call-tree-adams-bashforth-sync}.
+ \section{Staggered baroclinic time-stepping}
+ \label{sect:adams-bashforth-staggered}
+ \begin{figure}
+ \begin{center}
+ \resizebox{5.5in}{!}{\includegraphics{part2/adams-bashforth-staggered.eps}}
+ \end{center}
+ \caption{
+ A schematic of the explicit Adams-Bashforth and implicit time-stepping
+ phases of the algorithm but with staggering in time of thermodynamic
+ variables with the flow. Explicit thermodynamics tendencies are
+ evaluated at time level $n-1/2$ as a function of the thermodynamics
+ state at that time level $n$ and flow at time $n$ (dotted arrow). The
+ explicit tendency from the previous time level, $n-3/2$, is used to
+ extrapolate tendencies to $n$ (dashed arrow). This extrapolated
+ tendency allows thermo-dynamics variables to be stably integrated
+ forward-in-time to render an estimate ($*$-variables) at the $n+1/2$
+ time level (solid arc-arrow). The implicit-in-time operator ${\cal
+ L_{\theta,S}}$ is solved to yield the thermodynamic variables at time
+ level $n+1/2$. These are then used to calculate the hydrostatic
+ pressure/geo-potential, $\phi_{hyd}$ (vertical arrows). The
+ hydrostatic pressure gradient is evaluated directly an time level
+ $n+1/2$ in stepping forward the flow variables from $n$ to $n+1$
+ (solid arc-arrow). }
+ \label{fig:adams-bashforth-staggered}
+ \end{figure}
+ For well stratified problems, internal gravity waves may be the
+ limiting process for determining a stable time-step. In the
+ circumstance, it is more efficient to stagger in time the
+ thermodynamic variables with the flow
+ variables. Fig.~\ref{fig:adams-bashforth-staggered} illustrates the
+ staggering and algorithm. The key difference between this and
+ Fig.~\ref{fig:adams-bashforth-sync} is that the new thermodynamics
+ fields are used to compute the hydrostatic pressure at time level
+ $n+1/2$. The essentially allows the gravity wave terms to leap-frog in
+ time giving second order accuracy and more stability.
+ The essential change in the staggered algorithm is the calculation of
+ hydrostatic pressure which, in the context of the synchronous
+ algorithm involves replacing equation \ref{eq:phi-hyd-sync} with
+ \begin{displaymath}
+ \phi_{hyd}^n = \int b(\theta^{n+1},S^{n+1}) dr
+ \end{displaymath}
+ but the pressure gradient must also be taken out of the
+ Adams-Bashforth extrapolation. Also, retaining the integer time-levels,
+ $n$ and $n+1$, does not give a user the sense of where variables are
+ located in time.  Instead, we re-write the entire algorithm,
+ \ref{eq:Gt-n-sync} to \ref{eq:v-n+1-sync}, annotating the
+ position in time of variables appropriately:
+ \begin{eqnarray}
+ G_{\theta,S}^{n-1/2} & = & G_{\theta,S} ( u^n, \theta^{n-1/2}, S^{n-1/2} )
+ \label{eq:Gt-n-staggered} \\
+ G_{\theta,S}^{(n)} & = & (3/2+\epsilon_{AB}) G_{\theta,S}^{n-1/2}-(1/2+\epsilon_{AB}) G_{\theta,S}^{n-3/2}
+ \label{eq:Gt-n+5-staggered} \\
+ (\theta^*,S^*) & = & (\theta^{n},S^{n}) + \Delta t G_{\theta,S}^{(n)}
+ \label{eq:tstar-staggered} \\
+ (\theta^{n+1/2},S^{n+1/2}) & = & {\cal L}^{-1}_{\theta,S} (\theta^*,S^*)
+ \label{eq:t-n+1-staggered} \\
+ \phi^{n+1/2}_{hyd} & = & \int b(\theta^{n+1/2},S^{n+1/2}) dr
+ \label{eq:phi-hyd-staggered} \\
+ \vec{\bf G}_{\vec{\bf v}}^{n} & = & \vec{\bf G}_{\vec{\bf v}} ( \vec{\bf v}^n )
+ \label{eq:Gv-n-staggered} \\
+ \vec{\bf G}_{\vec{\bf v}}^{(n+1/2)} & = & (3/2 + \epsilon_{AB} ) \vec{\bf G}_{\vec{\bf v}}^{n} - (1/2 + \epsilon_{AB} ) \vec{\bf G}_{\vec{\bf v}}^{n-1}
+ \label{eq:Gv-n+5-staggered} \\
+ \vec{\bf v}^{*} & = & \vec{\bf v}^{n} + \Delta t \left( \vec{\bf G}_{\vec{\bf v}}^{(n+1/2)} - \nabla \phi_{hyd}^{n+1/2} \right)
+ \label{eq:vstar-staggered} \\
+ \vec{\bf v}^{**} & = & {\cal L}_{\vec{\bf v}}^{-1} ( \vec{\bf v}^* )
+ \label{eq:vstarstar-staggered} \\
+ \eta^* & = & \epsilon_{fs} \left( \eta^{n} +P-E+R \right)- \Delta t
+   \nabla \cdot H \widehat{ \vec{\bf v}^{**} }
+ \label{eq:nstar-staggered} \\
+ \nabla \cdot g H \nabla \eta^{n+1} - \frac{\epsilon_{fs} \eta^{n+1}}{\Delta t^2}
+ & = & - \frac{\eta^*}{\Delta t^2}
+ \label{eq:elliptic-staggered} \\
+ \vec{\bf v}^{n+1} & = & \vec{\bf v}^{*} - \Delta t g \nabla \eta^{n+1}
+ \label{eq:v-n+1-staggered}
+ \end{eqnarray}
+ The calling sequence is unchanged from
+ Fig.~\ref{fig:call-tree-adams-bashforth-sync}. The staggered algorithm
+ is activated with the run-time flag {\bf staggerTimeStep=.TRUE.} in
+ {\em PARM01} of {\em data}.
+ The only difficulty with this approach is apparent in equation
+ \ref{eq:Gt-n-staggered} and illustrated by the dotted arrow
+ connecting $u,v^n$ with $G_\theta^{n-1/2}$. The flow used to advect
+ tracers around is not naturally located in time. This could be avoided
+ by applying the Adams-Bashforth extrapolation to the tracer field
+ itself and advecting that around but this approach is not yet
+ available. We're not aware of any detrimental effect of this
+ feature. The difficulty lies mainly in interpretation of what
+ time-level variables and terms correspond to.
+ \section{Non-hydrostatic formulation}
+ \label{sect:non-hydrostatic}
+ The non-hydrostatic formulation re-introduces the full vertical
+ momentum equation and requires the solution of a 3-D elliptic
+ equations for non-hydrostatic pressure perturbation. We still
+ intergrate vertically for the hydrostatic pressure and solve a 2-D
+ elliptic equation for the surface pressure/elevation for this reduces
+ the amount of work needed to solve for the non-hydrostatic pressure.
+ The momentum equations are discretized in time as follows:
+ \begin{eqnarray}
+ \frac{1}{\Delta t} u^{n+1} + g \partial_x \eta^{n+1} + \partial_x \phi_{nh}^{n+1}
+ & = & \frac{1}{\Delta t} u^{n} + G_u^{(n+1/2)} \label{eq:discrete-time-u-nh} \\
+ \frac{1}{\Delta t} v^{n+1} + g \partial_y \eta^{n+1} + \partial_y \phi_{nh}^{n+1}
+ & = & \frac{1}{\Delta t} v^{n} + G_v^{(n+1/2)} \label{eq:discrete-time-v-nh} \\
+ \frac{1}{\Delta t} w^{n+1} + \partial_r \phi_{nh}^{n+1}
+ & = & \frac{1}{\Delta t} w^{n} + G_w^{(n+1/2)} \label{eq:discrete-time-w-nh} \\
+ \end{eqnarray}
+ which must satisfy the discrete-in-time depth integrated continuity,
+ equation~\ref{eq:discrete-time-backward-free-surface} and the local continuity equation
+ \begin{equation}
+ \partial_x u^{n+1} + \partial_y v^{n+1} + \partial_r w^{n+1} = 0
+ \label{eq:non-divergence-nh}
+ \end{equation}
+ As before, the explicit predictions for momentum are consolidated as:
  \begin{eqnarray*}
- \left[ 1 - \partial_r \kappa_v^\theta \partial_r \right]
+ u^* & = & u^n + \Delta t G_u^{(n+1/2)} \\
- \theta^{n+1/2} & = & \theta^*
+ v^* & = & v^n + \Delta t G_v^{(n+1/2)} \\
- \\
+ w^* & = & w^n + \Delta t G_w^{(n+1/2)}
- \left[ 1 - \partial_r \kappa_v^S \partial_r \right]
- S^{n+1/2} & = & S^*
- \end{eqnarray*}
- with
- \begin{eqnarray*}
- \theta^* & = &
- \theta ^{(n-1/2)} + \Delta t G_{\theta} ^{(n)}
- \\
- S^* & = &
- S ^{(n-1/2)} + \Delta t G_{S} ^{(n)}
  \end{eqnarray*}
- And
+ but this time we introduce an intermediate step by splitting the
- \begin{eqnarray*}
+ tendancy of the flow as follows:
- %{b'}^{n+1/2} & = & b'(\theta^{n+1/2},S^{n+1/2},r)
+ \begin{eqnarray}
- %\\
+ u^{n+1} = u^{**} - \Delta t \partial_x \phi_{nh}^{n+1}
- %\partial_r {\phi'_{hyd}}^{n+1/2} & = & {-b'}^{n+1/2}
+ & &
- {\phi'_{hyd}}^{n+1/2} & = & \int_{r'}^{R_o} b'(\theta^{n+1/2},S^{n+1/2},r) dr
+ u^{**} = u^{*} - \Delta t g \partial_x \eta^{n+1} \\
- %\label{eq-rtd-hyd}
+ v^{n+1} = v^{**} - \Delta t \partial_y \phi_{nh}^{n+1}
- \\
+ & &
- \vec{\bf v} ^{n+1}
+ v^{**} = v^{*} - \Delta t g \partial_y \eta^{n+1}
- + \Delta t {\bf \nabla}_h b_s {\eta}^{n+1}
+ \end{eqnarray}
- + \epsilon_{nh} \Delta t {\bf \nabla}_h {\phi'_{nh}}^{n+1}
+ Substituting into the depth integrated continuity
- - \partial_r A_v \partial_r \vec{\bf v}^{n+1}
+ (equation~\ref{eq:discrete-time-backward-free-surface}) gives
+ \begin{equation}
+ \partial_x H \partial_x \left( g \eta^{n+1} + \widehat{\phi}_{nh}^{n+1} \right)
+ +
+ \partial_y H \partial_y \left( g \eta^{n+1} + \widehat{\phi}_{nh}^{n+1} \right)
+  - \frac{\epsilon_{fs}\eta^*}{\Delta t^2}
+ = - \frac{\eta^*}{\Delta t^2}
+ \end{equation}
+ which is approximated by equation
+ \ref{eq:elliptic-backward-free-surface} on the basis that i)
+ $\phi_{nh}^{n+1}$ is not yet known and ii) $\nabla \widehat{\phi}_{nh}
+ << g \nabla \eta$. If \ref{eq:elliptic-backward-free-surface} is
+ solved accurately then the implication is that $\widehat{\phi}_{nh}
+ \approx 0$ so that thet non-hydrostatic pressure field does not drive
+ barotropic motion.
+ The flow must satisfy non-divergence
+ (equation~\ref{eq:non-divergence-nh}) locally, as well as depth
+ integrated, and this constraint is used to form a 3-D elliptic
+ equations for $\phi_{nh}^{n+1}$:
+ \begin{equation}
+ \partial_{xx} \phi_{nh}^{n+1} + \partial_{yy} \phi_{nh}^{n+1} +
+ \partial_{rr} \phi_{nh}^{n+1} =
+ \partial_x u^{**} + \partial_y v^{**} + \partial_r w^{*}
+ \end{equation}
+ The entire algorithm can be summarized as the sequential solution of
+ the following equations:
+ \begin{eqnarray}
+ u^{*} & = & u^{n} + \Delta t G_u^{(n+1/2)} \label{eq:ustar-nh} \\
+ v^{*} & = & v^{n} + \Delta t G_v^{(n+1/2)} \label{eq:vstar-nh} \\
+ w^{*} & = & w^{n} + \Delta t G_w^{(n+1/2)} \label{eq:wstar-nh} \\
+ \eta^* & = & \epsilon_{fs} \left( \eta^{n} +P-E+R \right)- \Delta t
+   \partial_x H \widehat{u^{*}}
+ + \partial_y H \widehat{v^{*}}
+ \\
+   \partial_x g H \partial_x \eta^{n+1}
+ + \partial_y g H \partial_y \eta^{n+1}
+ - \frac{\epsilon_{fs} \eta^{n+1}}{\Delta t^2}
  & = &
- \vec{\bf v}^*
+ - \frac{\eta^*}{\Delta t^2}
- %\label{eq-rtd-hmom}
+ \label{eq:elliptic-nh}
  \\
- \epsilon_{fs} {\eta}^{n+1} + \Delta t
+ u^{**} & = & u^{*} - \Delta t g \partial_x \eta^{n+1} \label{eq:unx-nh}\\
- {\bf \nabla}_h \cdot \int_{R_{min}}^{R_o} \vec{\bf v}^{n+1} dr
+ v^{**} & = & v^{*} - \Delta t g \partial_y \eta^{n+1} \label{eq:vnx-nh}\\
- & = &
+ \partial_{xx} \phi_{nh}^{n+1} + \partial_{yy} \phi_{nh}^{n+1} +
- \epsilon_{fs} {\eta}^{n} + \epsilon_{fw} \Delta_t (P-E)^{n}
+ \partial_{rr} \phi_{nh}^{n+1} & = &
- \\
+ \partial_x u^{**} + \partial_y v^{**} + \partial_r w^{*} \\
- \epsilon_{nh} \left( \dot{r} ^{n+1}
+ u^{n+1} & = & u^{**} - \Delta t \partial_x \phi_{nh}^{n+1} \label{eq:un+1-nh}\\
- + \Delta t \partial_r {\phi'_{nh}} ^{n+1}
+ v^{n+1} & = & v^{**} - \Delta t \partial_y \phi_{nh}^{n+1} \label{eq:vn+1-nh}\\
- \right)
+ \partial_r w^{n+1} & = & - \partial_x u^{n+1} - \partial_y v^{n+1}
- & = & \epsilon_{nh} \dot{r}^*
+ \end{eqnarray}
- %\label{eq-rtd-rdot}
+ where the last equation is solved by vertically integrating for
- \\
+ $w^{n+1}$.
- {\bf \nabla}_h \cdot \vec{\bf v}^{n+1} + \partial_r \dot{r}^{n+1}
- & = & 0
- %\label{eq-rtd-cont}
- \end{eqnarray*}
- with
- \begin{eqnarray*}
- \vec{\bf v}^* & = &
- \vec{\bf v} ^{n} + \Delta t \vec{\bf G}_{\vec{\bf v}} ^{(n+1/2)}
- + \Delta t  {\bf \nabla}_h {\phi'_{hyd}}^{n+1/2}
- \\
- \dot{r}^* & = &
- \dot{r} ^{n} + \Delta t G_{\dot{r}} ^{(n+1/2)}
- \end{eqnarray*}
- %---------------------------------------------------------------------
- \subsection{Surface pressure}
- Substituting \ref{eq-rtd-hmom} into \ref{eq-rtd-cont}, assuming
+ \section{Variants on the Free Surface}
- $\epsilon_{nh} = 0$ yields a Helmholtz equation for ${\eta}^{n+1}$:
+ We now describe the various formulations of the free-surface that
+ include non-linear forms, implicit in time using Crank-Nicholson,
+ explicit and [one day] split-explicit. First, we'll reiterate the
+ underlying algorithm but this time using the notation consistent with
+ the more general vertical coordinate $r$. The elliptic equation for
+ free-surface coordinate (units of $r$), corresponding to
+ \ref{eq:discrete-time-backward-free-surface}, and
+ assuming no non-hydrostatic effects ($\epsilon_{nh} = 0$) is:
  \begin{eqnarray}
  \epsilon_{fs} {\eta}^{n+1} -
- {\bf \nabla}_h \cdot \Delta t^2 (R_o-R_{min})
+ {\bf \nabla}_h \cdot \Delta t^2 (R_o-R_{fixed}) {\bf \nabla}_h b_s
- {\bf \nabla}_h b_s {\eta}^{n+1}
+ {\eta}^{n+1} = {\eta}^*
- = {\eta}^*
+ \label{eq-solve2D}
- \label{solve_2d}
  \end{eqnarray}
  where
  \begin{eqnarray}
  {\eta}^* = \epsilon_{fs} \: {\eta}^{n} -
- \Delta t {\bf \nabla}_h \cdot \int_{R_{min}}^{R_o} \vec{\bf v}^* dr
+ \Delta t {\bf \nabla}_h \cdot \int_{R_{fixed}}^{R_o} \vec{\bf v}^* dr
  \: + \: \epsilon_{fw} \Delta_t (P-E)^{n}
- \label{solve_2d_rhs}
+ \label{eq-solve2D_rhs}
  \end{eqnarray}
- Once ${\eta}^{n+1}$ has been found substituting into \ref{eq-rtd-hmom}
+ \fbox{ \begin{minipage}{4.75in}
- would yield $\vec{\bf v}^{n+1}$ if the model is hydrostatic
+ {\em S/R SOLVE\_FOR\_PRESSURE} ({\em solve\_for\_pressure.F})
- ($\epsilon_{nh}=0$):
+ $u^*$: {\bf GuNm1} ({\em DYNVARS.h})
+ $v^*$: {\bf GvNm1} ({\em DYNVARS.h})
+ $\eta^*$: {\bf cg2d\_b} (\em SOLVE\_FOR\_PRESSURE.h)
+ $\eta^{n+1}$: {\bf etaN} (\em DYNVARS.h)
+ \end{minipage} }
+ Once ${\eta}^{n+1}$ has been found, substituting into
+ \ref{eq:discrete-time-u,eq:discrete-time-v} yields $\vec{\bf v}^{n+1}$ if the model is
+ hydrostatic ($\epsilon_{nh}=0$):
  $$
  \vec{\bf v}^{n+1} = \vec{\bf v}^{*}
  - \Delta t {\bf \nabla}_h b_s {\eta}^{n+1}
-Line 352 
 $$
+Line 723 
 $$
  This is known as the correction step. However, when the model is
  non-hydrostatic ($\epsilon_{nh}=1$) we need an additional step and an
- additional equation for $\phi'_{nh}$. This is obtained by
+ additional equation for $\phi'_{nh}$. This is obtained by substituting
- substituting \ref{eq-rtd-hmom} and \ref{eq-rtd-rdot} into
+ \ref{eq:discrete-time-u-nh}, \ref{eq:discrete-time-v-nh} and \ref{eq:discrete-time-w-nh}
- \ref{eq-rtd-cont}:
+ into continuity:
  \begin{equation}
  \left[ {\bf \nabla}_h^2 + \partial_{rr} \right] {\phi'_{nh}}^{n+1}
  = \frac{1}{\Delta t} \left(
-Line 375 
 Finally, the horizontal velocities at th
+Line 746 
 Finally, the horizontal velocities at th
  - \epsilon_{nh} \Delta t {\bf \nabla}_h {\phi'_{nh}}^{n+1}
  \end{equation}
  and the vertical velocity is found by integrating the continuity
- equation vertically.
+ equation vertically.  Note that, for the convenience of the restart
- Note that, for convenience regarding the restart procedure,
+ procedure, the vertical integration of the continuity equation has
- the integration of the continuity equation has been
+ been moved to the beginning of the time step (instead of at the end),
- moved at the beginning of the time step (instead of at the end),
  without any consequence on the solution.
- Regarding the implementation, all those computation are done
+ \fbox{ \begin{minipage}{4.75in}
- within the routine {\it SOLVE\_FOR\_PRESSURE} and its dependent
+ {\em S/R CORRECTION\_STEP} ({\em correction\_step.F})
- {\it CALL}s.
- The standard method to solve the 2D elliptic problem (\ref{solve_2d})
+ $\eta^{n+1}$: {\bf etaN} (\em DYNVARS.h)
- uses the conjugate gradient method (routine {\it CG2D}); The
- the solver matrix and conjugate gradient operator are only function
+ $\phi_{nh}^{n+1}$: {\bf phi\_nh} (\em DYNVARS.h)
- of the discretized domain and are therefore evaluated separately,
- before the time iteration loop, within {\it INI\_CG2D}.
+ $u^*$: {\bf GuNm1} ({\em DYNVARS.h})
- The computation of the RHS $\eta^*$ is partly
- done in {\it CALC\_DIV\_GHAT} and in {\it SOLVE\_FOR\_PRESSURE}.
+ $v^*$: {\bf GvNm1} ({\em DYNVARS.h})
- The same method is applied for the non hydrostatic part, using
+ $u^{n+1}$: {\bf uVel} ({\em DYNVARS.h})
- a conjugate gradient 3D solver ({\it CG3D}) that is initialized
- in {\it INI\_CG3D}. The RHS terms of 2D and 3D problems
+ $v^{n+1}$: {\bf vVel} ({\em DYNVARS.h})
- are computed together, within the same part of the code.
+ \end{minipage} }
+ Regarding the implementation of the surface pressure solver, all
+ computation are done within the routine {\it SOLVE\_FOR\_PRESSURE} and
+ its dependent calls.  The standard method to solve the 2D elliptic
+ problem (\ref{eq-solve2D}) uses the conjugate gradient method (routine
+ {\it CG2D}); the solver matrix and conjugate gradient operator are
+ only function of the discretized domain and are therefore evaluated
+ separately, before the time iteration loop, within {\it INI\_CG2D}.
+ The computation of the RHS $\eta^*$ is partly done in {\it
+ CALC\_DIV\_GHAT} and in {\it SOLVE\_FOR\_PRESSURE}.
+ The same method is applied for the non hydrostatic part, using a
+ conjugate gradient 3D solver ({\it CG3D}) that is initialized in {\it
+ INI\_CG3D}. The RHS terms of 2D and 3D problems are computed together
+ at the same point in the code.
- \newpage
- %-----------------------------------------------------------------------------------
  \subsection{Crank-Nickelson barotropic time stepping}
- The full implicit time stepping described previously is unconditionally stable
+ The full implicit time stepping described previously is
- but damps the fast gravity waves, resulting in a loss of
+ unconditionally stable but damps the fast gravity waves, resulting in
- gravity potential energy.
+ a loss of potential energy.  The modification presented now allows one
- The modification presented hereafter allows to combine an implicit part
+ to combine an implicit part ($\beta,\gamma$) and an explicit part
- ($\beta,\gamma$) and an explicit part ($1-\beta,1-\gamma$) for the surface
+ ($1-\beta,1-\gamma$) for the surface pressure gradient ($\beta$) and
- pressure gradient ($\beta$) and for the barotropic flow divergence ($\gamma$).
+ for the barotropic flow divergence ($\gamma$).
  \\
  For instance, $\beta=\gamma=1$ is the previous fully implicit scheme;
  $\beta=\gamma=1/2$ is the non damping (energy conserving), unconditionally
-Line 417 
 In the code, $\beta,\gamma$ are defined
+Line 805 
 In the code, $\beta,\gamma$ are defined
  {\it implicSurfPress}, {\it implicDiv2DFlow}. They are read from
  the main data file "{\it data}" and are set by default to 1,1.
- Equations \ref{eq-rtd-hmom} and \ref{eq-rtd-eta} are modified as follows:
+ Equations \ref{eq:ustar-backward-free-surface} --
+ \ref{eq:vn+1-backward-free-surface} are modified as follows:
  $$
  \frac{ \vec{\bf v}^{n+1} }{ \Delta t }
  + {\bf \nabla}_h b_s [ \beta {\eta}^{n+1} + (1-\beta) {\eta}^{n} ]
-Line 426 
 $$
+Line 815 
 $$
  $$
  $$
  \epsilon_{fs} \frac{ {\eta}^{n+1} - {\eta}^{n} }{ \Delta t}
- + {\bf \nabla}_h \cdot \int_{R_{min}}^{R_o}
+ + {\bf \nabla}_h \cdot \int_{R_{fixed}}^{R_o}
  [ \gamma \vec{\bf v}^{n+1} + (1-\gamma) \vec{\bf v}^{n}] dr
  = \epsilon_{fw} (P-E)
  $$
-Line 439 
 where:
+Line 828 
 where:
  \\
  {\eta}^* & = &
  \epsilon_{fs} {\eta}^{n} + \epsilon_{fw} \Delta t (P-E)
- - \Delta t {\bf \nabla}_h \cdot \int_{R_{min}}^{R_o}
+ - \Delta t {\bf \nabla}_h \cdot \int_{R_{fixed}}^{R_o}
  [ \gamma \vec{\bf v}^* + (1-\gamma) \vec{\bf v}^{n}] dr
  \end{eqnarray*}
  \\
- In the hydrostatic case ($\epsilon_{nh}=0$),
+ In the hydrostatic case ($\epsilon_{nh}=0$), allowing us to find
- this allow to find ${\eta}^{n+1}$, according to:
+ ${\eta}^{n+1}$, thus:
  $$
  \epsilon_{fs} {\eta}^{n+1} -
- {\bf \nabla}_h \cdot \beta\gamma \Delta t^2 b_s (R_o - R_{min})
+ {\bf \nabla}_h \cdot \beta\gamma \Delta t^2 b_s (R_o - R_{fixed})
  {\bf \nabla}_h {\eta}^{n+1}
  = {\eta}^*
  $$
-Line 458 
 $$
+Line 847 
 $$
  $$
  The non-hydrostatic part is solved as described previously.
- \\ \\
- N.B:
+ Note that:
- \\
+ \begin{enumerate}
-  a) The non-hydrostatic part of the code has not yet been
+ \item The non-hydrostatic part of the code has not yet been
- updated, %since it falls out of the purpose of this test,
+ updated, so that this option cannot be used with $(\beta,\gamma) \neq (1,1)$.
- so that this option cannot be used with $(\beta,\gamma) \neq (1,1)$.
+ \item The stability criteria with Crank-Nickelson time stepping
- \\
+ for the pure linear gravity wave problem in cartesian coordinates is:
- b) To remind, the stability criteria with the Crank-Nickelson time stepping
+ \begin{itemize}
- for the pure linear gravity wave problem in cartesian coordinate is:
+ \item $\beta + \gamma < 1$ : unstable
- \\
+ \item $\beta \geq 1/2$ and $ \gamma \geq 1/2$ : stable
- $\star$~ $\beta + \gamma < 1$ : unstable
+ \item $\beta + \gamma \geq 1$ : stable if
- \\
- $\star$~ $\beta \geq 1/2$ and $ \gamma \geq 1/2$ : stable
- \\
- $\star$~ $\beta + \gamma \geq 1$ : stable if
- %, for all wave length $(k\Delta x,l\Delta y)$
  $$
  c_{max}^2 (\beta - 1/2)(\gamma - 1/2) + 1 \geq 0
  $$
-Line 488 
 $$
+Line 872 
 $$
  c_{max} =  2 \Delta t \: \sqrt{g H} \:
  \sqrt{ \frac{1}{\Delta x^2} + \frac{1}{\Delta y^2} }
  $$
+ \end{itemize}
+ \end{enumerate}

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