I solve a differential equation with vector inputs

**y' = f(t,y), y(t_0) = y_0**

where **y0 = y(x)**

using the explicit Euler method, which says that

**y_(i+1) = y_i + h*f(t_i, y_i)**

where **t** is a time vector, **h** is the step size, and **f** is the right-hand side of the differential equation.

The python code for the method looks like this:

```
for i in np.arange(0,n-1):
y[i+1,...] = y[i,...] + dt*myode(t[i],y[i,...])
```

The result is a **k,m** matrix **y**, where **k** is the size of the **t** dimension, and **m** is the size of **y**.

The vectors **y** and **t** are returned.

**t**, **x**, and **y** are passed to `scipy.interpolate.RectBivariateSpline(t, x, y, kx=1, ky=1)`

:

```
g = scipy.interpolate.RectBivariateSpline(t, x, y, kx=1, ky=1)
```

The resulting object `g`

takes new vectors `ti,xi ( g(p,q) )`

to give `y_int`

, which is **y** interpolated at the points defined by **ti** and **xi**.

Here is my problem:

The documentation for RectBivariateSpline describes the

`__call__`

method in terms of x and y:`__call__(x, y[, mth])`

*Evaluate spline at the grid points defined by the coordinate arrays*The matplotlib documentation for plot_surface uses similar notation:

`Axes3D.plot_surface(X, Y, Z, *args, **kwargs)`

with the important difference that X and Y are 2D arrays which are generated by`numpy.meshgrid()`

.

When I compute simple examples, the input order is the same in both and the result is exactly what I would expect. In my explicit Euler example, however, the initial order is `ti,xi`

, yet the surface plot of the interpolant output only makes sense if I reverse the order of the inputs, like so:

```
ax2.plot_surface(xi, ti, u, cmap=cm.coolwarm)
```

While I am glad that it works, I'm not satisfied because **I cannot explain why**, nor why (apart from the array geometry) it is necessary to swap the inputs. Ideally, I would like to restructure the code so that the input order is consistent.

Here is a working code example to illustrate what I mean:

```
# Heat equation example with explicit Euler method
import numpy as np
import matplotlib.pyplot as mplot
import matplotlib.cm as cm
import scipy.sparse as sp
import scipy.interpolate as interp
from mpl_toolkits.mplot3d import Axes3D
import pdb
# explicit Euler method
def eev(myode,tspan,y0,dt):
# Preprocessing
# Time steps
tspan[1] = tspan[1] + dt
t = np.arange(tspan[0],tspan[1],dt,dtype=float)
n = t.size
m = y0.shape[0]
y = np.zeros((n,m),dtype=float)
y[0,:] = y0
# explicit Euler recurrence relation
for i in np.arange(0,n-1):
y[i+1,...] = y[i,...] + dt*myode(t[i],y[i,...])
return y,t
# generate matrix A
# u'(t) = A*u(t) + g*u(t)
def a_matrix(n):
aa = sp.diags([1, -2, 1],[-1,0,1],(n,n))
return aa
# System of ODEs with finite differences
def f(t,u):
dydt = np.divide(1,h**2)*A.dot(u)
return dydt
# homogenous Dirichlet boundary conditions
def rbd(t):
ul = np.zeros((t,1))
return ul
# Initial value problem -----------
def main():
# Metal rod
# spatial discretization
# number of inner nodes
m = 20
x0 = 0
xn = 1
x = np.linspace(x0,xn,m+2)
# Step size
global h
h = x[1]-x[0]
# Initial values
u0 = np.sin(np.pi*x)
# A matrix
global A
A = a_matrix(m)
# Time
t0 = 0
tend = 0.2
# Time step width
dt = 0.0001
tspan = [t0,tend]
# Test r for stability
r = np.divide(dt,h**2)
if r <= 0.5:
u,t = eev(f,tspan,u0[1:-1],dt)
else:
print('r = ',r)
print('r > 0.5. Explicit Euler method will not be stable.')
# Add boundary values back
rb = rbd(t.size)
u = np.hstack((rb,u,rb))
# Interpolate heat values
# Create interpolant. Note the parameter order
fi = interp.RectBivariateSpline(t, x, u, kx=1, ky=1)
# Create vectors for interpolant
xi = np.linspace(x[0],x[-1],100)
ti = np.linspace(t0,tend,100)
# Compute function values from interpolant
u_int = fi(ti,xi)
# Change xi, ti in to 2D arrays
xi,ti = np.meshgrid(xi,ti)
# Create figure and axes objects
fig3 = mplot.figure(1)
ax3 = fig3.gca(projection='3d')
print('xi.shape =',xi.shape,'ti.shape =',ti.shape,'u_int.shape =',u_int.shape)
# Plot surface. Note the parameter order, compare with interpolant!
ax3.plot_surface(xi, ti, u_int, cmap=cm.coolwarm)
ax3.set_xlabel('xi')
ax3.set_ylabel('ti')
main()
mplot.show()
```