`plt.contour`

can be given arrays `X, Y, Z`

then it takes the `Z`

as the contour values and the `X`

and `Y`

are used on their respective axes. Here is a script that first makes some data to play with, then gets into an array of the form you describe:

```
import matplotlib.pyplot as plt
import numpy as np
# Make some test data
nx = 2
ny = 3
x = np.linspace(0, 3, nx)
y = np.linspace(50, 55, ny)
X, Y = np.meshgrid(x, y)
Z = np.sin(X) + Y
# Now get it into the form you describe
data = [[[x[i], y[j], Z[j, i]] for i in range(nx)] for j in range(ny)]
data = np.array(data)
print data
>>>
[[[ 0. 50. 50. ]
[ 3. 50. 50.14112001]]
[[ 0. 52.5 52.5 ]
[ 3. 52.5 52.64112001]]
[[ 0. 55. 55. ]
[ 3. 55. 55.14112001]]]
```

Note I am using a `numpy.array`

not just a normal list this is important in the next step. Lets split up that data as I presume you have done into the x and y values and the values themselves:

```
# Now extract the data
x_values = data[:, :, 0]
y_values = data[:, :, 1]
values = data[:, :, 2]
```

Now all of these things are `nx, ny`

arrays, that is they have the same shape as your `bsquare`

. You can check this by printing `values.shape`

and changing the integers `nx, ny`

. Now I will plot three things:

Firstly as you have done simply contour plot the values, this automatically adds the axes values

Secondly I plot using the arrays to give the correct scalings and

Finally I will plot the origin data set to show it properly recovers the data.

You will need to compare the axis values with where the fake data was created:

```
fig, axes = plt.subplots(ncols=3, figsize=(10, 2))
axes[0].contour(values)
axes[1].contour(x_values, y_values, values)
axes[2].contour(X, Y, Z)
```

How you implement this will largely depend on how you have imported your data. If you can simply turn it into a `numpy.array()`

then I think this will solve your issue.

Hopefully I understood your problem correctly.