Depending on whether you're generating `z`

or not, you have at least two different options.

If you're generating `z`

(e.g. you know the formula for it) it's very easy (see `method_1()`

below).

If you just have just a list of (`x`

,`y`

,`z`

) tuples, it's harder (see `method_2()`

below, and maybe `method_3()`

).

**Constants**

```
# min_? is minimum bound, max_? is maximum bound,
# dim_? is the granularity in that direction
min_x, max_x, dim_x = (-10, 10, 100)
min_y, max_y, dim_y = (-10, 10, 100)
```

**Method 1: Generating **`z`

```
# Method 1:
# This works if you are generating z, given (x,y)
def method_1():
x = np.linspace(min_x, max_x, dim_x)
y = np.linspace(min_y, max_y, dim_y)
X,Y = np.meshgrid(x,y)
def z_function(x,y):
return math.sqrt(x**2 + y**2)
z = np.array([z_function(x,y) for (x,y) in zip(np.ravel(X), np.ravel(Y))])
Z = z.reshape(X.shape)
plt.pcolormesh(X,Y,Z)
plt.show()
```

Which generates the following graph:

This is relatively easy, since you can generate `z`

at whatever points you want.

If you don't have that ability, and are given a fixed `(x,y,z)`

. You could do the following. First, I define a function that generates fake data:

```
def gen_fake_data():
# First we generate the (x,y,z) tuples to imitate "real" data
# Half of this will be in the + direction, half will be in the - dir.
xy_max_error = 0.2
# Generate the "real" x,y vectors
x = np.linspace(min_x, max_x, dim_x)
y = np.linspace(min_y, max_y, dim_y)
# Apply an error to x,y
x_err = (np.random.rand(*x.shape) - 0.5) * xy_max_error
y_err = (np.random.rand(*y.shape) - 0.5) * xy_max_error
x *= (1 + x_err)
y *= (1 + y_err)
# Generate fake z
rows = []
for ix in x:
for iy in y:
z = math.sqrt(ix**2 + iy**2)
rows.append([ix,iy,z])
mat = np.array(rows)
return mat
```

Here, the returned matrix looks like:

```
mat = [[x_0, y_0, z_0],
[x_1, y_1, z_1],
[x_2, y_2, z_2],
...
[x_n, y_n, z_n]]
```

**Method 2: Interpolating given **`z`

points over a regular grid

```
# Method 2:
# This works if you have (x,y,z) tuples that you're *not* generating, and (x,y) points
# may not fall evenly on a grid.
def method_2():
mat = gen_fake_data()
x = np.linspace(min_x, max_x, dim_x)
y = np.linspace(min_y, max_y, dim_y)
X,Y = np.meshgrid(x, y)
# Interpolate (x,y,z) points [mat] over a normal (x,y) grid [X,Y]
# Depending on your "error", you may be able to use other methods
Z = interpolate.griddata((mat[:,0], mat[:,1]), mat[:,2], (X,Y), method='nearest')
plt.pcolormesh(X,Y,Z)
plt.show()
```

This method produces the following graphs:

*error = 0.2*

*error = 0.8*

**Method 3: No Interpolation (constraints on sampled data)**

There's a third option, depending on how your `(x,y,z)`

is set up. This option requires two things:

- The number of different x sample positions equals the number of different y sample positions.
- For every possible unique (x,y) pair, there is a corresponding (x,y,z) in your data.

From this, it follows that the number of `(x,y,z)`

pairs must be equal to the square of the number of unique x points (where the number of unique x positions equals the number of unique y positions).

In general, with sampled data, this *will not* be true. But if it is, you can avoid having to interpolate:

```
def method_3():
mat = gen_fake_data()
x = np.unique(mat[:,0])
y = np.unique(mat[:,1])
X,Y = np.meshgrid(x, y)
# I'm fairly sure there's a more efficient way of doing this...
def get_z(mat, x, y):
ind = (mat[:,(0,1)] == (x,y)).all(axis=1)
row = mat[ind,:]
return row[0,2]
z = np.array([get_z(mat,x,y) for (x,y) in zip(np.ravel(X), np.ravel(Y))])
Z = z.reshape(X.shape)
plt.pcolormesh(X,Y,Z)
plt.xlim(min(x), max(x))
plt.ylim(min(y), max(y))
plt.show()
```

*error = 0.2*

*error = 0.8*

`x`

,`y`

,`z`

? Is there one`z`

value for each value of`x`

, or for the cartesian product of`x`

and`y`

. That is`len(z)==len(x)==len(y)`

or`len(z)==len(x)*len(y)`

?