# How to make a matrix out of existing xyz data

I want to use matplotlib.pyplot.pcolormesh to plot a depth plot.

What I have is a xyz file Three columns i.e. x(lat), y(lon), z(dep).

All columns are of equal length

pcolormesh require matrices as input. So using numpy.meshgrid I can transform the x and y into matrices:

``````xx,yy = numpy.meshgrid(x_data,y_data)
``````

This works great...However, I don't know how to create Matrix of my depth (z) data... How do I create a matrix for my z_data that corresponds to my x_data and y_data matrices?

• Do you want a 3d matrix? Because numpy has support for n-dimensional matricies Commented Aug 3, 2016 at 17:16
• What's the size of your `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)`? Commented Aug 3, 2016 at 18:05
• Valid question, there is a z value for each x,y combo Commented Aug 3, 2016 at 18:13
• @HenryPrickett-Morgan I don't think so...it's a 2d xy plot, and I want them color coded based on my z values. I want to use pcolormesh method for this from the matplotlib module Commented Aug 3, 2016 at 18:16

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:

1. The number of different x sample positions equals the number of different y sample positions.
2. 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

• Tnx ! I'll take a look at it. To answer your question all my data is fixed. Commented Aug 3, 2016 at 18:41
• Hey, thanks again so much. I'm trying out option two...but I'm not sure how to generate fake data. I mean, I know how the syntax work, but should I generate it in any specific way? Could you elaborate just a bit more please? Commented Aug 4, 2016 at 7:29
• @J.A.Cado sure, and sorry for the confusion. I generated fake data because I didn't have yours. You shouldn't need to, just use your real data. The only thing you need to look out for is that your data is arranged similarly (see the few lines right under "Here, the returned matrix looks like:"). Commented Aug 4, 2016 at 8:07
• holy cow I did it! That's amazing! Thanks so much :D Just a side question, I was working with pandas dataframes, and just loading in the column of the dataframe in scypy.griddata method. `girddata((df['x'],df['y']),df['z'],(X,Y),method='linear')`But that never worked, it gave me errors about dimensions not being correct. Any idea why that wouldn't work? cheers! Commented Aug 4, 2016 at 9:15
• Option 2 worked for me I have my own data set, with actual data from the field. Length of columns (x,y,z) are all equal. and each (x,y,z) pair is unique, Commented Aug 4, 2016 at 9:17