1D/2D/3D solutions for all three growth models. Problem in the linear solution.

growing_domain/diffusion_on_growing_domain.py

@@ -47,11 +47,12 @@ class GrowthDiffusion(object):
                         + self.Dc * df.inner(df.nabla_grad(self.c), df.nabla_grad(tc))
                         + self.Dc * df.inner(df.nabla_grad(self.c), df.nabla_grad(tc))
                         - df.inner(self.reaction_rate * self.c, tc) ) * df.dx
                         - df.inner(self.reaction_rate * self.c, tc) ) * df.dx
 
 
-    def solve(self):
-        times = np.arange(0, self.maxtime+self.timestep, self.timestep)
-        fname = params['timestamp'] + '_concentration' 
-        cFile = df.XDMFFile(fname+ '.xdmf')
 
 
+    def solve(self):
+        savesteps = int(self.savetime/self.timestep)
+        maxsteps = int(self.maxtime/self.timestep)
+        self.time = 0.0
+        cFile = df.XDMFFile('%s_concentration.xdmf' %params['timestamp'])
 
 
         # initial condition
         # initial condition
         r2 = "+".join(['x['+str(i)+']*x['+str(i)+']' for i in range(self.dimension)])
         r2 = "+".join(['x['+str(i)+']*x['+str(i)+']' for i in range(self.dimension)])
@@ -59,22 +60,24 @@ class GrowthDiffusion(object):
         c0 = df.Expression(c0, pi=np.pi, m=1, L=self.system_size, degree=1)            
         c0 = df.Expression(c0, pi=np.pi, m=1, L=self.system_size, degree=1)            
         self.c0.assign(df.project(c0, self.SFS))
         self.c0.assign(df.project(c0, self.SFS))
         # save data
         # save data
-        cFile.write_checkpoint(self.c0, fname, times[0])
+        cFile.write_checkpoint(self.c0, 'concentration', self.time)
 
 
         # time stepping
         # time stepping
-        for i in progressbar.progressbar(range(1, len(times))):
+        for steps in progressbar.progressbar(range(1, maxsteps + 1)):
             # get velocity
             # get velocity
-            self.sigma.t = times[i-1]
+            self.sigma.t = self.time
             self.velocity.assign(df.project(self.sigma*self.growth_direction, self.VFS))
             self.velocity.assign(df.project(self.sigma*self.growth_direction, self.VFS))
             # solve
             # solve
             df.solve(self.form == 0, self.c)
             df.solve(self.form == 0, self.c)
             # update
             # update
             self.c0.assign(self.c)
             self.c0.assign(self.c)
             # save data
             # save data
-            cFile.write_checkpoint(self.c0, fname, times[i], append=True)
+            if steps % savesteps == 0:
+                cFile.write_checkpoint(self.c0, 'concentration', self.time, append=True)
             # move mesh
             # move mesh
             displacement = df.project(self.velocity*self.timestep, self.VFS)
             displacement = df.project(self.velocity*self.timestep, self.VFS)
             df.ALE.move(self.mesh, displacement)
             df.ALE.move(self.mesh, displacement)
+            self.time += self.timestep
 
 
         cFile.close()
         cFile.close()
     
     
@@ -95,5 +98,5 @@ if __name__ == '__main__':
     gd = GrowthDiffusion(params)
     gd = GrowthDiffusion(params)
     gd.solve()
     gd.solve()
     
     
-    with open(params['timestamp'] + '_parmeters.json', "w") as fp:
+    with open(params['timestamp'] + '_parameters.json', "w") as fp:
         json.dump(params, fp, indent=4)    
         json.dump(params, fp, indent=4)    
\ No newline at end of file

growing_domain/notes.tex

-\documentclass[11pt, reqno]{report}
-\usepackage{amssymb, amsmath, datetime, xcolor, soul, graphicx}
+\documentclass[11pt, reqno]{amsart}
+\usepackage{amssymb,amsmath,datetime,soul,graphicx,geometry}
+\usepackage[dvipsnames]{xcolor}
 \linespread{1.25}
 \linespread{1.25}
-\usepackage[colorlinks=true, citecolor=blue, urlcolor=blue]{hyperref}
+\usepackage[colorlinks=true,citecolor=RoyalBlue,urlcolor=RoyalBlue]{hyperref}
 
 
 % shortcuts
 % shortcuts
 \newcommand{\vect}[1]{\boldsymbol{#1}}
 \newcommand{\vect}[1]{\boldsymbol{#1}}
@@ -13,243 +14,201 @@
 
 
 \begin{document}
 \begin{document}
 
 
-\title{Diffusion on a growing domains}
+\title{Diffusion in isotropically growing domains}
 \date{\currenttime, \today}
 \date{\currenttime, \today}
 \maketitle
 \maketitle
 
 
 Largely following \href{https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0117949}{Exact Solutions of Linear Reaction-Diffusion Processes on a Uniformly Growing Domain: Criteria for Successful Colonization}, M J Simpson, PLoS One (2015).
 Largely following \href{https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0117949}{Exact Solutions of Linear Reaction-Diffusion Processes on a Uniformly Growing Domain: Criteria for Successful Colonization}, M J Simpson, PLoS One (2015).
 
 
-\section{Diffusion on a growing disk}
-\subsection{Kinematics}
-
-We consider a linear reaction-diffusion process on a growing disk labelled by points $\vect{r} = (r, \varphi)$ with $0 < r < R(t)$ and $0 \leq \varphi < 2\pi$ where $R(t)$ is the increasing radius of the domain. Domain growth is associated with a \emph{radial} velocity field $\vect{v} = v(r,t) \, \uvec{r}$ which causes points on a circle of radius $r$ to move to a circle of radius $r + v(r,t) \, \tau $ in a short time $\tau$. Thus,
-\eqn{r \to r^{\prime} = r + v(r, t)\tau.\label{eq:rprime}} 
-And, similarly, 
-\eqn{r + \Delta r \to r^{\prime} + \Delta r^{\prime} = r + \Delta r + v(r + \Delta r, t)\tau .\label{eq:rprimeplusdeltarprime}} 
-Subtracting Eq(\ref{eq:rprime}) from Eq(\ref{eq:rprimeplusdeltarprime}),
-\begin{equation}
-\begin{split}
-\Delta r^{\prime} &= \Delta r + \tau[v(r + \Delta r, t) - v(r,t)] \\
-&\approx \Delta r \left( 1 + \tau \frac{\partial v}{\partial r}\right)
-\end{split}
-\end{equation}
-Integrating both sides, 
-\eq{
-R^{\prime}(t) = R(t) + \tau \int_0^{R(t)} \frac{\partial v}{\partial r} dr
+\section{Kinematics}
+
+We consider a linear reaction-diffusion process on a growing $n-$dimensional domain labelled by points $\vect{r} = (r, \uvec{n})$ where $0 < r < R(t)$ with $R(t)$ is the increasing radius of the domain and $\uvec{n}$ is a unit-vector indicating a direction ($\uvec{n}$ only exists for $n \geq 2$). Domain growth is associated with a \emph{radial} velocity field $\vect{v} = v(r,t) \, \uvec{r}$ which causes points at a distance $r$ from the origin to move to a distance $r + v(r,t) \, \Delta t $ in a short time $\Delta t$. Thus points at distances $r$ and $r + \Delta r$, respectively, move to
+\eqn{r \to r^{\prime} &= r + v(r, t) \;\tau,
+\\
+r + \Delta r \to r^{\prime} + \Delta r^{\prime} &= r + \Delta r + v(r + \Delta r, t) \; \Delta t.} 
+Thus
+\eqn{
+\Delta r^{\prime} = \Delta r + \Delta t \; \big[ v(r + \Delta r, t) - v(r,t) \big] 
+\approx 
+\Delta r \left( 1 + \Delta t \frac{\partial v}{\partial r}\right)
 }
 }
-or
+implying
 \eqn{
 \eqn{
+R^{\prime}(t) = R(t) + \Delta t \int_0^{R(t)} \frac{\partial v}{\partial r} dr
+\qquad
+\implies
+\qquad
 \frac{dR(t)}{dt} = \int_0^{R(t)} \frac{\partial v}{\partial r} dr
 \frac{dR(t)}{dt} = \int_0^{R(t)} \frac{\partial v}{\partial r} dr
-.
-\label{eq:growing_radius}
 }
 }
-We consider uniform growth, i.e., $\partial_r v$ is independent of $r$ but potentially depends on time $t$,  so that we have $\partial_r v = \sigma(t)$. Combining this with \eqref{eq:growing_radius} gives
+We consider uniform growth, i.e., $\partial_r v \equiv \sigma(t)$ is independent of $r$ but could potentially depend on time $t$. Thus
 \eqn{
 \eqn{
-\frac{\partial v}{\partial r} = \sigma(t) = \frac{1}{R(t)} \frac{dR(t)}{dt}.
+\sigma(t) = \frac{1}{R(t)} \frac{dR(t)}{dt}.
 \label{eq:growth_rate}
 \label{eq:growth_rate}
 }
 }
-Assuming that the circular domain elongates with its center fixed, i.e., $v(0,t) = 0$, integrating \eqref{eq:growth_rate} gives
+We impose the boundary condition $v(0,t) = 0$ using which, on integrating \eqref{eq:growth_rate}, we find
 \eqn{
 \eqn{
-v(r,t) = \frac{r}{R(t)} \frac{dR(t)}{dt}.
+v(r,t) = \frac{r}{R(t)} \frac{dR(t)}{dt} = \sigma(t) \; r.
 }
 }
 
 
-\subsection{Mass conservation}
+\section{Mass conservation}
 
 
 We now consider the conservation of a mass density $C(\vect{r}, t)$, assuming that it evolves according to a linear reaction-diffusion mechanism. The associated conservation statement on the growing domain can be written as
 We now consider the conservation of a mass density $C(\vect{r}, t)$, assuming that it evolves according to a linear reaction-diffusion mechanism. The associated conservation statement on the growing domain can be written as
 \eqn{
 \eqn{
 \partial_t C = D \nabla^2 C - \nabla \cdot (\vect{v} C) + k \, C,
 \partial_t C = D \nabla^2 C - \nabla \cdot (\vect{v} C) + k \, C,
 \label{eq:general_reaction_diffusion}
 \label{eq:general_reaction_diffusion}
 }
 }
-where $D>0$ and $k$ are the diffusion constant and reaction rate respectively.
-
-We assume azimuthal symmetry $C(\vect{r}, t) = C(r, t)$, i.e., the dynamics is independent of $\varphi$. Then
+where $D>0$ and $k$ are the diffusion constant and reaction rate respectively. Assuming a solution that only depends on the growth direction, i.e., $C(\vect{r}, t) = C(r, t)$, we get
 \eqn{
 \eqn{
-\frac{\partial C}{\partial t} = D \, \frac{1}{r} \, \frac{\partial}{\partial r} \left(r \frac{\partial C}{\partial r} \right) - \frac{1}{r} \, \frac{\partial (r v C)}{\partial r}  + k\,C,
+\frac{\partial C}{\partial t} = \frac{D}{r^{n-1}} \, \frac{\partial}{\partial r} \left(r^{n-1} \frac{\partial C}{\partial r} \right) - \frac{1}{r^{n-1}} \, \frac{\partial (r^{n-1} v C)}{\partial r}  + k\,C,
+\\
+= \frac{D}{r^{n-1}} \, \frac{\partial}{\partial r} \left(r^{n-1} \frac{\partial C}{\partial r} \right) - \frac{\sigma(t)}{r^{n-1}} \, \frac{\partial (r^{n} C)}{\partial r}  + k\,C.
 \label{eq:azimuthal_symmetry}
 \label{eq:azimuthal_symmetry}
 }
 }
-and impose zero diffusive flux conditions $\partial_r C = 0$ at $r=0$ and at $r=R(t)$. With some given initial conditions $C(r, 0)$ our aim is to find the exact solution of \eqref{eq:azimuthal_symmetry}.
+We impose zero diffusive flux conditions $\partial_r C = 0$ at $r=0$ and at $r=R(t)$. With some given initial conditions $C(r, 0)$ our aim is to find the exact solution of \eqref{eq:azimuthal_symmetry}.
 
 
 
 
-\subsection{Exact solution}
+\section{Rescaling}
 
 
-We first transform the spatial variable to a fixed domain $\xi = \dfrac{r}{R(t)}$. Then
+We first transform the spatial variable to a fixed domain:
+\eqn{ r \to \xi = \frac{r}{R}.}
+This leads to
 \eqn{
 \eqn{
-\frac{\partial C}{\partial t} \to \frac{\partial C}{\partial t} - \frac{v}{R(t)} \frac{\partial C}{\partial \xi}
+\frac{\partial}{\partial t} \to \frac{\partial}{\partial t} - \sigma \; \xi \frac{\partial}{\partial \xi},
+\qquad \qquad
+\frac{\partial}{\partial r} \to \frac{1}{R} \frac{\partial}{\partial \xi}
 }
 }
+which implies
 \eqn{
 \eqn{
-\frac{\partial C}{\partial r} \to \frac{1}{R(t)} \frac{\partial C}{\partial \xi}
+\frac{\partial C}{\partial t} = 
+\frac{D }{\xi^{n-1} R^2} \, \frac{\partial}{\partial \xi} \left(\xi^{n-1} \frac{\partial C}{\partial \xi} \right)  + (k - n \, \sigma) C.
 }
 }
-Then Eq(\ref{eq:azimuthal_symmetry}) becomes:
-\eqn{\frac{\partial C}{\partial t} = \frac{D}{\xi R^2(t)} \frac{\partial}{\partial \xi} \left( \xi \frac{\partial C}{\partial \xi} \right) + \left(k - 2 \sigma(t)\right) C}
-We now transform the variable $t: t \to T = \int_0^t \frac{D}{R^2(s)} ds$, giving
-\eqn{\frac{\partial C}{\partial T} = \frac{1}{\xi} \frac{\partial}{\partial \xi} \left( \xi \frac{\partial C}{\partial \xi} \right) + \frac{R^2(t)}{D}\left(k - 2 \sigma(t) \right) C}
-Finally, we express the second term on the RHS as a function of $T$ to write:
-\eqn{\frac{\partial C}{\partial T} = \frac{1}{\xi} \frac{\partial}{\partial \xi} \left( \xi \frac{\partial C}{\partial \xi} \right) + f(T) C}
-The above equation can be solved easily by separation of variables. Writing $C(\xi, T) = u(\xi) w(T)$,
-\eqn{\frac{1}{w} \frac{dw}{dt} = \frac{1}{u \xi} \frac{d}{d \xi} \left( \xi \frac{du}{d \xi} \right) + f(T)}
-Thus, 
-\eqn{\frac{1}{w} \frac{dw}{dT} - f(T) = \frac{1}{u \xi} \frac{d}{d \xi} \left( \xi \frac{du}{d \xi} \right) = -n^2}
-Solving the $w$ equation first:
-\eqn{w(T) = w(0) \exp\left[-n^2 T + \int_0^T f(T^{\star}) dT^\star \right]}
-The $u$ equation reads:
-\eqn{\xi \frac{d^2 u}{d \xi^2} + \frac{du}{d \xi} + n^2 u \xi = 0}
-This is the Bessel equation of zeroth order, having solutions
-\eqn{u(\xi) = c_1 J_0 (\xi n) + c_2 yY_0 (\xi n)}
-Thus, the exact solution in the $(\xi, T)$ coordinates is :
-\eqn{C(\xi, T) = \left[ a_1 J_0 (\xi n) + a_2 Y_0 (\xi n)\right] \exp\left[-n^2 T + \int_0^T f(T^\star) dT^\star \right]}
-Since we want the solution to be bounded at $\xi = 0$, we keep only the $J_0$ term:
-\eqn{C(\xi, T) = a_1 J_0 (\xi n) \exp\left[-n^2 T + \int_0^T f(T^\star) dT^\star \right]}  
-If we had Dirichlet boundary conditions at $\xi = 1$, $n$ would be the solution of 
-\eqn{J_0 (n) = 0}
-i.e $n$'s are the roots of the zeroth bessel function.
-Thus, the most general solution is:
-\eqn{C(\xi, T) = \sum_{n} a_n J_0(\eta_n \xi) \exp\left[-\eta_n^2 T + \int_0^T f(T^\star) dT^\star \right]
-\label{general_sol}}
-where $\eta_n$ is the $n$th root of the zeroth Bessel function for Dirichlet boundary conditions. \\$a_n$ is determined by the initial conditions. Let us take 
-\eqn{C(\xi, 0) = J_0(\eta_m \xi) = \sum_{n} a_n J_0(\eta_n \xi)}
-where the last equality follows by putting $T=0$ in Eq(\ref{general_sol}). Now using the orthogonality relation
-\eq{\int_0^a J_v \left( \eta_{\nu p}\frac{\xi}{a}\right)J_v \left( \eta_{\nu q}\frac{\xi}{a}\right) \xi d \xi = \frac{a^2}{2}[J_{\nu+1} (\eta_{\nu p})]^2 \delta_{pq}}
-where $\eta_{\nu p}$ and $\eta_{\nu q}$ are the $p$th and $q$th roots of the $\nu$th bessel function, we get 
-\eqn{a_{n=m} = 1, a_{n \neq m} = 0}.
-In summary, the solution to our problem for the initial condition $C(\xi, 0) = J_0(\eta_m \xi)$ where $\eta_m$ is the mth root of $j_0$ is:
-\eqn{C(\xi, T) = J_0(\eta_{m} \xi) \exp \left[-\eta_m^2 T + \int_0^T f(T^\star)dT^\star \right]}.                                                                        
-\subsection{Specific examples}
-\subsubsection*{No growth}
-In this case, $R(t) = R, \sigma(t) = 0, f(T^\star) = R^2 k/D$.
-This gives \eq{C(\xi, T) =  J_0 (\eta_m \xi) e^{-\eta_m^2 T} e^{R^2 k T/D}}
-Plugging in $T = D t/R^2 $ and $\xi = r/R$,
-\eqn{C(r,t) = J_0 (\eta_m r/R) e^{-\frac{\eta_m^2 D t}{R^2}}e^{kt}}
-\subsubsection{Exponential domain growth}
-In this case, $R(t) = R_0 e^{\alpha t}, \sigma(t)=\alpha$
-\eq{ T = \frac{D(1 - e^{-2 \alpha t})}{2 \alpha R_0^2}}
-And \eq{f(	T^\star) = \frac{R_0^2 (k - 2 \alpha)}{D - 2 \alpha R_0^2 T^{\star}}} 
-Then,
-\eq{C(\xi, T) = J_0(\eta_m \xi) e^{-\eta_m^2 T} \left(\frac{D}{D - 2\alpha R_0^2 T}\right)^{(k-2\alpha)/2\alpha}}
-and \eqn{C(r,t) = J_0\left(\eta_m \frac{r}{R(t)}\right) \exp\left( -\frac{\eta_m^2 D(1 - e^{-2 \alpha t})}{2 \alpha R_0^2}\right) e^{(k - 2\alpha)t}}
-\subsubsection{Linear domain growth}
-In this case, $R(t)=R_0 + bt, \sigma(t) = b/R(t)$.\\
-Further, \eq{T = \frac{D t}{R(t) R_0}}, or, 
-\eq{t = \frac{R_0^2 T}{D - R_0 b T}}
-And \eq{f(T^\star) = \frac{R_0}{(D - R_0 bT^\star)^2} (k D R_0 - 2 b D + 2bR_0T^\star)}
-Then
-\eq{C(\xi, T) = J_0(\eta_m \xi) e^{-\eta_m^2 T} e^{\frac{(kR_0^2 - 2b + 2 R_0)T}{D - R_0 bT}}\left(\frac{D - R_0 bT}{D}\right)^\frac{2 R_0}{b}}
-\eqn{C(r, t) = J_0\left(\eta_{m} \frac{n r}{R(t)}\right)e^{-\frac{\eta_m^2 D t}{R(t) R_0}} \left(\frac{R_0}{R(t)}\right)^{2R_0/b} e^{kt} e^{\frac{2( R_0-b)t}{R_0^2}}}
-
-\section{Diffusion in a growing sphere}
-\subsection{Kinematics}
-We consider a linear reaction-diffusion process on a growing sphere labelled by points $\vect{r} = (r, \theta, \varphi)$ with $0 < r < R(t)$, $0 \leq \varphi < 2\pi$ and $0 \leq \theta \leq \pi$ where $R(t)$ is the increasing radius of the domain. Domain growth is associated with a \emph{radial} velocity field $\vect{v} = v(r,t) \, \uvec{r}$ which causes points on the surface of the sphere of radius $r$ to move to a circle of radius $r + v(r,t) \, \tau $ in a short time $\tau$. Thus,
-\eqn{r \to r^{\prime} = r + v(r, t)\tau.\label{eq:rprime}} 
-And, similarly, 
-\eqn{r + \Delta r \to r^{\prime} + \Delta r^{\prime} = r + \Delta r + v(r + \Delta r, t)\tau .\label{eq:rprimeplusdeltarprime}} 
-Subtracting Eq(\ref{eq:rprime}) from Eq(\ref{eq:rprimeplusdeltarprime}),
-\begin{equation}
-\begin{split}
-\Delta r^{\prime} &= \Delta r + \tau[v(r + \Delta r, t) - v(r,t)] \\
-&\approx \Delta r \left( 1 + \tau \frac{\partial v}{\partial r}\right)
-\end{split}
-\end{equation}
-Integrating both sides, 
-\eq{
-R^{\prime}(t) = R(t) + \tau \int_0^{R(t)} \frac{\partial v}{\partial r} dr
-}
-or
+Next, we transform the variable:
 \eqn{
 \eqn{
-\frac{dR(t)}{dt} = \int_0^{R(t)} \frac{\partial v}{\partial r} dr
-.
-\label{eq:growing_radius}
+t \to \tau  = \int_0^t ds \; \frac{D}{R^2(s)}.
 }
 }
-We consider uniform growth, i.e., $\partial_r v$ is independent of $r$ but potentially depends on time $t$,  so that we have $\partial_r v = \sigma(t)$. Combining this with \eqref{eq:growing_radius} gives
+Then
 \eqn{
 \eqn{
-\frac{\partial v}{\partial r} = \sigma(t) = \frac{1}{R(t)} \frac{dR(t)}{dt}.
-\label{eq:growth_rate}
+\frac{\partial C}{\partial \tau} = 
+\frac{1}{\xi^{n-1}} \, \frac{\partial}{\partial \xi} \left(\xi^{n-1} \frac{\partial C}{\partial \xi} \right)  + f(\tau) C
+\label{eq:nondim_eqn}
 }
 }
-Assuming that the circular domain elongates with its center fixed, i.e., $v(0,t) = 0$, integrating \eqref{eq:growth_rate} gives
+where
 \eqn{
 \eqn{
-v(r,t) = \frac{r}{R(t)} \frac{dR(t)}{dt}.
+f(t(\tau)) = \frac{R(t(\tau))^2}{D} \big[k - n \, \sigma(t(\tau)) \big].
 }
 }
 
 
-\subsection{Mass conservation}
+\section{Exact solutions}
 
 
-We now consider the conservation of a mass density $C(\vect{r}, t)$, assuming that it evolves according to a linear reaction-diffusion mechanism. The associated conservation statement on the growing domain can be written as
+We use separation of variables to solve \eqref{eq:nondim_eqn}. Writing $C(\xi, \tau) = u(\xi) \; w(\tau)$,
+\eqn{\frac{1}{w} \frac{dw}{d\tau} - f(\tau)= \frac{1}{u \, \xi^{n-1}} \frac{d}{d \xi} \left( \xi^{n-1} \frac{du}{d \xi} \right).}
+With $-\omega^2$ as a separation constant, we get
 \eqn{
 \eqn{
-\partial_t C = D \nabla^2 C - \nabla \cdot (\vect{v} C) + k \, C,
-\label{eq:general_reaction_diffusion}
+\frac{dw}{d\tau} = \big[ f(\tau) - \omega^2 \big] w
+\qquad
+\implies
+\qquad
+w(\tau) = w(0) \exp\left[-\omega^2 \tau + \int_0^\tau ds\; f(s) \right],
 }
 }
-where $D>0$ and $k$ are the diffusion constant and reaction rate respectively.
-
-We assume azimuthal symmetry $C(\vect{r}, t) = C(r, t)$, i.e., the dynamics is independent of $\varphi$. Then
+and
 \eqn{
 \eqn{
-\frac{\partial C}{\partial t} = D \, \frac{1}{r^2} \, \frac{\partial}{\partial r} \left(r^2 \frac{\partial C}{\partial r} \right) - \frac{1}{r^2} \, \frac{\partial (r^2 v C)}{\partial r}  + k \, C,
-\label{eq:azimuthal_symmetry}
-}
-and impose zero diffusive flux conditions $\partial_r C = 0$ at $r=0$ and at $r=R(t)$. With some given initial conditions $C(r, 0)$ our aim is to find the exact solution of \eqref{eq:azimuthal_symmetry}.
-
-
-\subsection{Exact solution}
-
-We first transform the spatial variable to a fixed domain $\xi = \dfrac{r}{R(t)}$. Then
+\frac{d^2 u}{d\xi^2} + \frac{(n-1)}{\xi} \frac{du}{d\xi} + \omega^2 u = 0.
+\label{eq:u_eqn}
+}
+We need to find solutions of \eqref{eq:u_eqn} with the boundary conditions that $u'(\xi) = 0$ at both $\xi=0$ and $\xi=1$.
+\begin{itemize}
+\item When $n=1$, we get
+\eqn{u'' + \omega^2 u = 0,}
+and thus we need $\omega=m\pi, m \in \mathbb{Z}$ to satisfy the boundary conditions. The general solution is thus
+\eqn{u(\xi, \tau) = \sum_{m=0}^{\infty} a_m \cos\left(m \pi \xi \right) \; \exp\left[-m^2 \pi^2 \tau + \int_0^\tau ds\; f(s) \right].}
+%
+\item When $n=2$, we get
+\eqn{\xi \, u'' + u' + \omega^2 \, \xi \, u = 0,}
+the solutions of which are the zeroth-order Bessel functions $J_0(\omega\xi)$ and $Y_0(\omega\xi)$. Requiring $u$ to be bounded at $\xi=0$, we neglect the $Y_0$ solution. Imposing the boundary condition
+\eqn{\frac{dJ_0(z)}{dz}\bigg\vert_{z=\omega}=0 \qquad \implies J_1(\omega)=0,
+\label{eq:bc_n2}}
+determines the allowed values of $\omega$ as the zeroes of the 1st-order Bessel function. The general solution is thus
+\eqn{u(\xi, \tau) = \sum_{\omega} a_{\omega}  \, J_0(\omega \xi) \; \exp\left[-\omega^2 \tau + \int_0^\tau ds\; f(s) \right],}
+where the summation is over those values of $\omega$ satisfying \eqref{eq:bc_n2}.
+%
+\item When $n=3$, we get
+\eqn{\xi \, u'' + 2 \, u' + \omega^2 \, \xi \, u = 0,}
+the solutions of which are the zeroth-order \emph{spherical} Bessel functions
 \eqn{
 \eqn{
-\frac{\partial C}{\partial t} \to \frac{\partial C}{\partial t} - \frac{v}{R(t)} \frac{\partial C}{\partial \xi}
-}
+j_0(\omega \xi) = \frac{\sin (\omega \xi)}{\omega \xi},
+\qquad \mathrm{and} \qquad 
+y_0(\omega \xi) = -\frac{\cos (\omega \xi)}{\omega \xi}.} 
+Requiring $u$ to be bounded at $\xi=0$, we neglect the $y_0$ solution. Imposing the boundary condition
+\eqn{\frac{dj_0(z)}{dz}\bigg\vert_{z=\omega}=0 \qquad \implies \qquad
+\tan \omega = \omega,
+\label{eq:bc_n3}}
+determines the allowed values of $\omega$. The general solution is thus
+\eqn{u(\xi, \tau) = \sum_{\omega} a_{\omega} \, \frac{\sin (\omega \xi)}{\omega \xi} \; \exp\left[-\omega^2 \tau + \int_0^\tau ds\; f(s) \right],}
+where the summation is over those values of $\omega$ satisfying \eqref{eq:bc_n3}.
+\end{itemize}
+
+\section{Three cases}
+
+\subsection{Non-growing domain}
+With $R(t) = R_0$ in this case, we get 
+\eqn{\sigma(t)=0, \qquad \tau=\frac{Dt}{R_0^2}, \qquad f=\frac{R_0^2k}{D}.} 
+Hence $\tau \to\infty$ as $t\to\infty$. Thus
+\begin{itemize}
+%
+\item $n=1$
 \eqn{
 \eqn{
-\frac{\partial C}{\partial r} \to \frac{1}{R(t)} \frac{\partial C}{\partial \xi}
-}
-Then Eq(\ref{eq:azimuthal_symmetry}) becomes:
-\eqn{\frac{\partial C}{\partial t} = \frac{D}{\xi^2 R^2(t)} \frac{\partial}{\partial \xi} \left( \xi^2 \frac{\partial C}{\partial \xi} \right) + \left(k - 3 \sigma(t)\right) C}
-We now transform the variable $t: t \to T = \int_0^t \frac{D}{R^2(s)} ds$, giving
-\eqn{\frac{\partial C}{\partial T} = \frac{1}{\xi^2} \frac{\partial}{\partial \xi} \left( \xi^2 \frac{\partial C}{\partial \xi} \right) + \frac{R^2(t)}{D}\left(k - 3 \sigma(t) \right) C}
-Finally, we express the second term on the RHS as a function of $T$ to write:
-\eqn{\frac{\partial C}{\partial T} = \frac{1}{\xi^2} \frac{\partial}{\partial \xi} \left( \xi^2 \frac{\partial C}{\partial \xi} \right) + f(T) C}
-The above equation can be solved easily by separation of variables. Writing $C(\xi, T) = u(\xi) v(T)$,
-\eqn{\frac{1}{v} \frac{dv}{dt} = \frac{1}{u \xi^2} \frac{d}{d \xi} \left( \xi^2 \frac{du}{d \xi} \right) + f(T)}
-Thus, 
-\eqn{\frac{1}{v} \frac{dv}{dT} - f(T) = \frac{1}{u \xi^2} \frac{d}{d \xi} \left( \xi^2 \frac{du}{d \xi} \right) = -n^2}
-Solving the $v$ equation first:
-\eqn{v(T) = v(0) \exp\left[-n^2 T + \int_0^T f(T^{\star}) dT^\star \right]}
-And the $u$ equation reads:
-\eqn{\frac{d^2 u}{d \xi^2} + \frac{2}{\xi} \frac{du}{d \xi} + n^2 u = 0}
-This is the Bessel equation of zeroth order, having solutions
-\eqn{u(\xi) = c_1 j_0 (n \xi) + c_2 y_0 (n \xi)}
-where $j_0, y_0$ are spherical bessel functions given by 
-\eq{j_0 (n \xi) = \frac{\sin(n \xi)}{n \xi}}
-\eq{y_0 (n \xi) = -\frac{\cos(n \xi)}{n \xi}}
-Thus, the exact solution in the $(\xi, T)$ coordinates is :
-\eqn{C(\xi, T) = \left[ a_1 j_0 (n \xi) + a_2 y_0 (n \xi)\right] \exp\left[-n^2 T + \int_0^T f(T^\star) dT^\star \right]}
-Since we want the solution to be bounded at $\xi = 0$, we keep only the $j_0$ term:
-\eqn{C(\xi, T) = a_1 j_0 (n \xi) \exp\left[-n^2 T + \int_0^T f(T^\star) dT^\star \right]}  
-If we have Dirichlet boundary conditions at $\xi =0, 1$ then $n$ can be determined to be the solution of $j_0(n) = 0$, i.e.
-\eq{n = m \pi, m \in \mathbb{Z}}
-Thus, the most general solution is:
-\eq{C(\xi, T) = \sum_{m} a_m j_0(m \pi \xi) \exp\left[-(m \pi)^2 T + \int_0^T f(T^\star) dT^\star \right]}
-We now determine $a_m$ by the initial conditions. Let us take 
-\eqn{C(\xi, 0) = j_0(p \pi \xi) = \sum_m a_m j_0(m \pi \xi)}
-Using the orthogonality relation
-\eqn{\int_0^a j_{\nu}\left(\eta_{\nu p}\frac{\xi}{a}\right) j_{\nu}\left(\eta_{\nu q}\frac{\xi}{a}\right) \xi^2 d \xi = \frac{a^3}{2} [j_{\nu + 1}(\eta_{\nu p})]^2 \delta_{pq}}
-where $\eta_{\nu p}$ and $\eta_{\nu q}$ are the $p$th and $q$th roots of the $\nu$th bessel function, we get
-\eqn{a_{m=p}=1, a_{m \neq p} = 0}
-And thus the solution for initial condition $C(\xi, 0) = j_0(p \pi \xi)$ and Dirichlet boundaries at $\xi = 0,1$ is:
-\eqn{C(\xi, T) = j_0(p \pi \xi) \exp\left[-(p \pi)^2 T + \int_0^T f(T^\star) dT^\star\right]}
-\subsection{Specific examples}
-\subsubsection*{No growth}
-In this case, $R(t) = R, \sigma(t) = 0, f(T^\star) = R^2 k/D$.
-This gives \eq{C(\xi, T) = j_0(p \pi \xi) e^{-p^2 \pi^2 T} e^{R^2 k T/D}}
-Plugging in $T = D t/R^2 $ and $\xi = r/R$,
-\eqn{C(r,t) = j_0\left(p \pi \frac{r}{R(t)}\right) e^{-\frac{p^2 \pi^2 D t}{R^2}}e^{kt}}
-\subsubsection*{Exponential domain growth}
-In this case, $R(t) = R_0 e^{\alpha t}, \sigma(t)=\alpha$
-\eq{ T = \frac{D(1 - e^{-2 \alpha t})}{2 \alpha R_0^2}}
-And \eq{f(	T^\star) = \frac{R_0^2 (k - 3 \alpha)}{D - 2 \alpha R_0^2 T^{\star}}} 
-Then,
-\eq{C(\xi, T) = j_0(p \pi \xi) e^{-(p \pi)^2 T} \left(\frac{D}{D - 2 \alpha R_0^2 T}\right)^{(k-3\alpha)/2\alpha}}
-and \eqn{C(r,t) = j_0\left(p \pi \frac{r}{R(t)}\right) \exp\left[-\frac{(p \pi)^2 D(1 - e^{-2 \alpha t})}{2 \alpha R_0^2} \right] e^{(k-3\alpha)t}}
-\subsubsection*{Linear domain growth}
-In this case, $R(t)=R_0 + bt, \sigma(t) = b/R(t)$.\\
-Further, \eq{T = \frac{D t}{R(t) R_0}}, or, 
-\eq{t = \frac{R_0^2 T}{D - R_0 b T}}
-And \eq{f(T^\star) = \frac{R_0}{(D - R_0 bT^\star)^2} (k D R_0 - 3 b D + 3bR_0T^\star)}
-Then
-\eq{C(\xi, T) = j_0(p \pi \xi) e^{-p^2 \pi^2 T} e^{\frac{(k R_0 + 3 - 3b) R_0 T}{D - R_0 b T}}\left(\frac{D - R_0 b T}{D}\right)^{3/b}}
-\eqn{C(r, t) = \left(\frac{R_0}{R(t)} \right)^{3/b} j_0\left(\frac{p \pi r}{R(t)}\right)e^{-\frac{p^2 \pi^2 D t}{R(t) R_0}} e^{kt} e^{\frac{3(1-b)t}{R_0}} }
-\end{document}
+C(r,t) = \sum_{m=0}^{\infty} a_m \cos\left(\frac{m \pi r}{R_0} \right) \; \exp\left(-\frac{m^2 \pi^2 D t}{R_0^2} + k t \right),
+\qquad \mathrm{with} \quad m \in \mathbb{Z}
+}
+%
+\item $n=2$
+\eqn{C(r, t) = \sum_{\omega} a_{\omega}  \, J_0\left(\frac{\omega r}{R_0} \right) \; \; \exp\left(-\frac{\omega^2 D t}{R_0^2} + k t \right),
+\qquad \mathrm{with} \quad J_1(\omega)=0.
+}
+%
+\item $n=3$
+\eqn{C(r, t) = \sum_{\omega} a_{\omega}  \, \frac{R_0}{\omega r} \; \sin \left(\frac{\omega r}{R_0}\right) \; \; \exp\left(-\frac{\omega^2 D t}{R_0^2} + k t \right),
+\qquad \mathrm{with} \quad \tan \omega = \omega.}
+\end{itemize}
+
+
+\subsection{Exponential domain growth}
+
+With $R(t) = R_0 e^{\alpha t}$ in this case, we get, 
+\eqn{\sigma(t)=\alpha, \qquad \tau=\frac{D \; (1-e^{-2\alpha t})}{2\alpha R_0^2} , \qquad \int_0^\tau f(s) ds = \ln\left(\frac{D}{D - 2 \alpha R_0^2 \tau}\right)^{(k-n\alpha)/2\alpha} .}
+Hence $\tau \to D/(2\alpha R_0^2)$ as $t\to\infty$. Thus
+\begin{itemize}
+%
+\item $n=1$
+\eqn{C(r,t) = \sum_{m=0}^\infty a_m \cos\left( \frac{m \pi r}{R(t)}\right) \exp\left[{-\frac{m^2 \pi^2 D}{2 \alpha R_0^2} (1 - e^{-2\alpha t})+t(k-\alpha)}\right],
+\qquad \mathrm{with} \quad m \in \mathbb{Z}}
+%
+\item $n=2$
+\eqn{C(r,t) = \sum_{\omega}^\infty a_\omega J_0\left( \frac{\omega r}{R(t)}\right) \exp\left[{-\frac{\omega^2 D}{2 \alpha R_0^2} (1 - e^{-2\alpha t})+t(k-2\alpha)}\right],
+\qquad \mathrm{with} \quad J_1(\omega)=0.}
+%
+\item $n=3$
+\eqn{C(r,t) = \sum_{\omega}^\infty a_\omega \frac{ R(t)}{\omega r} \sin\left( \frac{\omega r}{R(t)}\right) \exp\left[{-\frac{\omega^2 D}{2 \alpha R_0^2} (1 - e^{-2\alpha t})+t(k-3\alpha)}\right],
+\qquad \mathrm{with} \quad \tan \omega = \omega.}
+\end{itemize}
+
+
+\subsection{Linear domain growth}
+With $R(t) = R_0 + \alpha t$ in this case, we get 
+\eqn{\sigma(t) = \frac{\alpha}{R_0 + \alpha t}, \qquad\tau=\frac{D \; t}{R_0 (R_0 + \alpha t)} , \qquad \int_0^\tau f(s) ds = \frac{R_0^2 k \tau}{(D - \alpha R_0 \tau)} + \ln \left( \frac{D - R_0 \alpha \tau}{D}\right)^{n}.}
+Hence $\tau \to D/(\alpha R_0)$ as $t\to\infty$. Thus
+\begin{itemize}
+%
+\item $n=1$
+\eqn{C(r,t) = \sum_{m=0}^\infty a_m \cos\left( \frac{m \pi r}{R(t)}\right) \exp\left[{-\frac{m^2 \pi^2 D t}{R(t) R_0} + tk}\right] \left(\frac{R_0}{R(t)}\right),
+\qquad \mathrm{with} \quad m \in \mathbb{Z}}
+%
+\item $n=2$
+\eqn{C(r,t) = \sum_{\omega}^\infty a_\omega J_0\left( \frac{\omega r}{R(t)}\right) \exp\left[{-\frac{\omega^2 D t}{R(t) R_0} + tk}\right] \left(\frac{R_0}{R(t)}\right)^2,
+\qquad \mathrm{with} \quad J_1(\omega)=0.}
+%
+\item $n=3$
+\eqn{C(r,t) = \sum_{\omega}^\infty a_\omega \frac{ R(t)}{\omega r} \sin\left( \frac{\omega r}{R(t)}\right) \exp\left[{-\frac{\omega^2 D t}{R(t) R_0} + tk} \right] \left(\frac{R_0}{R(t)}\right)^3,
+\qquad \mathrm{with} \quad \tan \omega = \omega.}
+\end{itemize}
 
 
 \end{document}
 \end{document}

growing_domain/parameters.json

 {
 {
     "dimension" : 2,
     "dimension" : 2,
-    "resolution" : 5,
+    "resolution" : 15,
     "system_size" : 1,
     "system_size" : 1,
 
 
     "Dc" : 0.1,
     "Dc" : 0.1,
-    "growth" : "exponential",
+    "growth" : "linear",
     "growth_parameter" : 0.1,
     "growth_parameter" : 0.1,
     "reaction_rate" : 0.0,
     "reaction_rate" : 0.0,
 
 
     "timestep" : 0.01,
     "timestep" : 0.01,
-    "maxtime" : 1.0
+    "savetime": 0.1,
+    "maxtime" : 5.0
 }
 }

growing_domain/viz_growing_domains.py

+import dolfin as df
+import numpy as np
+import vedo as vd
+import matplotlib.pyplot as plt
+from mpl_toolkits.axes_grid1.inset_locator import inset_axes
+import progressbar
+import os
+import json
+import h5py
+from tempfile import TemporaryDirectory
+
+
+def get_data(params, DIR=''):
+    savesteps = int(params['maxtime']/params['savetime'])
+    times = np.arange(savesteps+1) * params['savetime']    
+
+    # Read mesh geometry from h5 file
+    var = 'concentration'
+    h5 = h5py.File(os.path.join(DIR, '%s_%s.h5' % (params['timestamp'], var)), "r")
+    # should be in the loop if remeshing
+    topology = np.array(h5['%s/%s_0/mesh/topology'%(var,var)])
+    geometry = []
+    for i in range(len(times)):
+        geometry.append(np.array(h5['%s/%s_%d/mesh/geometry'%(var,var,i)]))
+    h5.close()
+    geometry = np.array(geometry)
+    
+    # create a mesh
+    if params['dimension']==1:
+        mesh = df.IntervalMesh(params['resolution'], 0, params['system_size'])
+    else:
+        mesh = df.Mesh()
+        editor = df.MeshEditor()
+        editor.open(mesh, 
+                    type='triangle' if params['dimension']==2 else 'tetrahedron', 
+                    tdim=params['dimension'], gdim=params['dimension'])
+        editor.init_vertices(len(geometry[0]))
+        editor.init_cells(len(topology))
+        for i in range(len(geometry[0])):
+            editor.add_vertex(i, geometry[0][i])
+        for i in range(len(topology)):
+            editor.add_cell(i, topology[i])
+        editor.close()
+    
+    # Read concentration data
+    concentration = np.zeros((len(times), len(geometry[0])))
+    cFile = os.path.join(DIR, '%s_%s.xdmf' % (params['timestamp'],var))
+    with df.XDMFFile(cFile) as cFile:
+        for steps in range(savesteps+1):
+            mesh.coordinates()[:] = geometry[steps]
+            VFS = df.FunctionSpace(mesh, 'P', 1)
+            c = df.Function(VFS)
+            cFile.read_checkpoint(c, var, steps)
+            concentration[steps] = c.compute_vertex_values(mesh)
+
+    return (times, geometry, topology, concentration)
+
+def visualize(params, DIR='', offscreen=False):
+    n_cmap_vals = 16
+    scalar_cmap = 'viridis'
+    
+    (times, geometry, topology, concentration) = get_data(params, DIR)
+    if params['dimension']==2:
+        geometry = np.dstack((geometry, np.zeros(geometry.shape[0:2])))
+
+    cmin, cmax = np.min(concentration), np.max(concentration)
+    
+    plotter = vd.plotter.Plotter(axes=0)
+    
+    poly = vd.utils.buildPolyData(geometry[0], topology)
+    scalar_actor = vd.mesh.Mesh(poly)
+    #scalar_actor.computeNormals(points=True, cells=True)
+    scalar_actor.pointdata['concentration'] = concentration[0]
+    scalar_actor.cmap(scalar_cmap, concentration[0], vmin=cmin, vmax=cmax, n=n_cmap_vals)
+    scalar_actor.addScalarBar(title = r'$c$', 
+                pos=(0.8, 0.04), nlabels=2,
+                titleYOffset=15, titleFontSize=28, size=(100, 600))
+    plotter += scalar_actor
+    
+    
+    def update(idx):
+        scalar_actor.points(pts=geometry[idx], transformed=False)
+        scalar_actor.pointdata['concentration'] = concentration[idx]
+        
+    def slider_update(widget, event):
+        value = widget.GetRepresentation().GetValue()
+        idx = (abs(times-value)).argmin()
+        update(idx)
+        
+    slider = plotter.addSlider2D(slider_update, pos=[(0.1,0.94), (0.5,0.94)],
+                            xmin=times[0], xmax=times.max(), 
+                            value=times[0], title=r"$t/\tau$")
+
+    
+    vd.show(interactive=(not offscreen), zoom=0.8)
+    
+    # make movie
+    if offscreen:
+        FPS = 10
+        movFile = '%s.mov' % params['timestamp']
+        fps = float(FPS)
+        command = "ffmpeg -y -r"
+        options = "-b:v 3600k -qscale:v 4 -vcodec mpeg4"
+        tmp_dir = TemporaryDirectory()
+        get_filename = lambda x: os.path.join(tmp_dir.name, x)
+        for tt in range(len(times)):
+            idx = (abs(times-times[tt])).argmin()
+            update(idx)
+            slider.GetRepresentation().SetValue(times[tt])
+            fr = get_filename("%03d.png" % tt)
+            vd.io.screenshot(fr)
+        os.system(command + " " + str(fps)
+                    + " -i " + tmp_dir.name + os.sep
+                    + "%03d.png " + options + " " + movFile)
+        tmp_dir.cleanup()
+    
+def visualize1(params, DIR='', offscreen=False):
+    n_cmap_vals = 10
+    scalar_cmap = 'viridis'
+    vector_color = '#ffffff'
+    vector_scale = 0.1
+    savesteps = int(params['maxtime']/params['savetime'])
+    times = params['alpha'] * np.arange(savesteps+1) * params['savetime']
+    halftime = int(len(times)/2)
+
+    mesh = get_mesh_from_xdmf(DIR, params)
+
+    print('Reading polarity')
+    polarity = np.zeros((len(times), mesh.num_vertices(), 3))
+    polarity_functions = []
+    VFS = df.VectorFunctionSpace(mesh, 'P', 1)
+    p = df.Function(VFS)
+    with df.XDMFFile(os.path.join(DIR,'%s_polarity.xdmf' % params['timestamp'])) as pFile:
+        for steps in progressbar.progressbar(range(savesteps+1)):
+            pFile.read_checkpoint(p, 'polarity', steps)
+            polarity_functions.append(p)
+            vector_values = p.compute_vertex_values(mesh)
+            polarity[steps] = vector_values.reshape(3, int(vector_values.shape[0]/3)).T
+    pmag = np.linalg.norm(polarity, axis=2)
+    pmin, pmax = 0, np.max(pmag)
+    polarity = polarity / pmax
+
+
+    # load previously computed convergence data
+    data = np.loadtxt(os.path.join(DIR, '%s.dat' % params['timestamp']))
+
+    fig1, ax = plt.subplots(1)
+    fig1.subplots_adjust(left=0.15, bottom=0.15, right=0.9, top=0.85)
+    ax.plot(times, data[:,1])
+    ax.set_xlabel(r'$\alpha t$')
+    ax.set_ylabel(r'$\int_{\Gamma} (\mathbf{p}_{t+\Delta t}-\mathbf{p}_{t})^2$')
+    axins = inset_axes(ax, width="50%", height="40%")
+    axins.plot(times[halftime:], data[halftime:,1])
+    fig1.savefig(os.path.join(DIR, '%s_pnorm.pdf' % params['timestamp']), transparent=True)
+
+
+    VSH_labels = [r'$\mathbf{\Psi}_{10}$',
+                r'$\mathbf{\Phi}_{10}$',
+                r'$\mathbf{\Psi}_{11}$',
+                r'$\mathbf{\Phi}_{11}$',
+                r'$\mathbf{\Psi}_{20}$',
+                r'$\mathbf{\Phi}_{20}$',
+                r'$\mathbf{\Psi}_{21}$',
+                r'$\mathbf{\Phi}_{21}$',
+                r'$\mathbf{\Psi}_{22}$',
+                r'$\mathbf{\Phi}_{22}$'
+    ]
+
+    fig2, ax = plt.subplots(1)
+    fig2.subplots_adjust(left=0.15, bottom=0.15, right=0.9, top=0.85)
+    ax.set_xlim(times[halftime:].min(), times.max())
+    for i in range(len(VSH_labels)):
+        ax.plot(times[halftime:], data[halftime:, i+2], label=VSH_labels[i], lw=1)
+    ax.set_xlabel(r'$\alpha t$')
+    ax.set_ylabel(r'$\sqrt{p^{\Psi}_{lm} (p^{\Psi}_{lm})^{\ast}}, \ \sqrt{p^{\Phi}_{lm} (p^{\Phi}_{lm})^{\ast}}$')
+    ax.legend(loc=0, ncol=5, fontsize='small', bbox_to_anchor=(0.1, 1))
+    fig2.savefig(os.path.join(DIR, '%s_modes.pdf' % params['timestamp']), transparent=True)
+    if not offscreen:
+        fig1.show()
+        fig2.show()
+
+
+    (_, _, _, _, normal, _, _) = compute_geometric_quantities(params['meshfile'])
+    projector = df.Identity(3) - df.outer(normal, normal)
+    TFS = df.TensorFunctionSpace(mesh, 'P', 1)
+    p = polarity_functions[-1]
+    grad_p = df.project(projector * df.grad(p) * projector, TFS)
+    div_p = df.tr(grad_p)
+    omega = df.skew(grad_p)
+    Theta = df.assemble(df.inner(div_p, div_p) * df.dx(mesh))
+    Phi   = df.assemble(df.inner(omega, omega) * df.dx(mesh))
+
+    defect_locations, defect_eigvals = find_defects(mesh, p, grad_p, pmag[-1])
+    assert len(defect_locations)==2
+
+    params['Theta_norm'] = Theta
+    params['Phi_norm'] = Phi
+
+    # clean up
+    for key in ["converged", "dtpnorm_ave"]:
+        if key in params.keys():
+            del params[key]
+            
+    with open(os.path.join(DIR, params['timestamp'] + '_polarity.json'), "w") as fp:
+        json.dump(params, fp, indent=4)
+    
+
+    plotter = vd.plotter.Plotter(axes=4)
+    poly = vd.utils.buildPolyData(mesh.coordinates(), mesh.cells())
+    scalar_actor = vd.mesh.Mesh(poly)
+    scalar_actor.computeNormals(points=True, cells=True)
+    
+    scalar_actor.cmap(scalar_cmap, pmag[0], vmin=pmin, vmax=pmax, n=n_cmap_vals)
+    scalar_actor.addScalarBar(
+        title = r'$\sqrt{\left(\frac{\beta}{\alpha}\right)} \; \left\vert\mathbf{p}\right\vert$', 
+        pos=(0.8, 0.1), nlabels=2,
+        titleYOffset=15, titleFontSize=28, size=(100, 600))
+    scalar_actor.scalarbar.SetLabelFormat("%0.1f")
+    plotter.add(scalar_actor)
+    
+    defects = vd.shapes.Spheres(defect_locations, c='red', r=0.02)
+    plotter.add(defects)
+    vec = defect_locations[1] - defect_locations[0]
+    uvec = vec / np.linalg.norm(vec)
+    line = vd.Line(-1.1*uvec, 1.1*uvec, lw=6, c='black')
+    plotter.add(line)
+
+    endPoints = mesh.coordinates() + vector_scale * polarity[0]
+    vector_actor = vd.shapes.Arrows(mesh.coordinates(), endPoints)
+    vector_actor.color(vector_color)
+    plotter.add(vector_actor)
+    def update(idx):
+        nonlocal vector_actor
+        scalar_actor.pointdata['polarity'] = pmag[idx]
+        scalar_actor.cmap(scalar_cmap, pmag[idx], vmin=pmin, vmax=pmax, n=n_cmap_vals)
+        plotter.remove(vector_actor)
+        endPoints = mesh.coordinates() + vector_scale * polarity[idx]
+        vector_actor = vd.shapes.Arrows(mesh.coordinates(), endPoints)
+        vector_actor.color(vector_color)
+        plotter.add(vector_actor)
+    def slider_update(widget, event):
+        value = widget.GetRepresentation().GetValue()
+        idx = (abs(times-value)).argmin()
+        update(idx)
+        
+    slider = plotter.addSlider2D(slider_update, pos=[(0.25,0.05), (0.75,0.05)],
+                            xmin=times[0], xmax=times.max(), 
+                            value=times[0], title=r"$\alpha \, t$")
+    slider.GetRepresentation().SetLabelFormat('%0.1f')
+    
+    # optimized camera position
+    cam = dict(pos=(4.952, 3.107, 1.804),
+           focalPoint=(0.07537, 0.1585, -0.07462),
+           viewup=(-0.2810, -0.1402, 0.9494),
+           distance=6.000,
+           clippingRange=(2.836, 10.26))
+
+    vd.show(interactive=(not offscreen), camera=cam, zoom=1.4)
+
+
+    # make movie
+    if offscreen:
+        print('Saving movie...')
+        FPS = 10
+        movFile = os.path.join(DIR, '%s_polarity.mov' % params['timestamp'])
+        fps = float(FPS)
+        command = "ffmpeg -y -r"
+        options = "-b:v 3600k -qscale:v 4 -vcodec mpeg4"
+        tmp_dir = TemporaryDirectory()
+        get_filename = lambda x: os.path.join(tmp_dir.name, x)
+        for tt in progressbar.progressbar(range(len(times))):
+            idx = (abs(times-times[tt])).argmin()
+            update(idx)
+            slider.GetRepresentation().SetValue(times[tt])
+            fr = get_filename("%03d.png" % tt)
+            vd.io.screenshot(fr)
+        os.system(command + " " + str(fps)
+                    + " -i " + tmp_dir.name + os.sep
+                    + "%03d.png " + options + " " + movFile)
+        tmp_dir.cleanup()
+       
+if __name__ == '__main__':
+    import argparse, json
+    parser = argparse.ArgumentParser()
+    parser.add_argument('-j','--jsonfile', help='parameters file', required=True)
+    parser.add_argument('--onscreen', action=argparse.BooleanOptionalAction)
+    args = parser.parse_args()
+
+    with open(args.jsonfile) as jsonFile:
+        params = json.load(jsonFile)
+        
+    (times, geometry, topology, concentration) = get_data(params, DIR='')
+    visualize(params, DIR=os.path.dirname(args.jsonfile), offscreen=(not args.onscreen))
+    
\ No newline at end of file