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To state it in a general form, I'm looking for a way to join several points with a gradient color line using matplotlib, and I'm not finding it anywhere. To be more specific, I'm plotting a 2D random walk with a one color line. But, as the points have a relevant sequence, I would like to look at the plot and see where the data has moved. A gradient colored line would do the trick. Or a line with gradually changing transparency.

I'm just trying to improve the vizualization of my data. Check out this beautiful image produced by the ggplot2 package of R. I'm looking for the same in matplotlib. Thanks.

enter image description here

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1  
I'm not sure what you mean by a 'gradient colour line': do you mean that (eg) the walk starts with a blue line and gradually changes to red at the end? Can you supply a minimal example of your current code that plots the walk with a one-colour line? –  mathematical.coffee Dec 14 '11 at 7:26
    
I don't know of any way of plotting gradients in lines with matplotlib, although it would be nice. I can suggest you to use pycairo instead, there you can use gradients for sure and get a lot more of control over the plot. Though you will lose some convenience from matplotlib, like axis and automatic data range :-( –  dsign Dec 14 '11 at 7:30
    
are you sure? :( do you know of any plans to incorporate that feature? I've never heard of pycairo. can you give me some hints? @mathematical.coffee: yes, that's what I mean. the code can be a simple data set (some points and that's all) –  PDRX Dec 14 '11 at 9:04
    
Maybe you can try something like this. –  Avaris Dec 14 '11 at 9:19
    
@PedroMC I'm still not clear on what you want, but I took a guess and posted an answer below. If that is not what you are looking for, please help me understand what you are trying to do (can you provide an example?). –  Yann Dec 14 '11 at 14:05

4 Answers 4

up vote 7 down vote accepted

I recently answered a question with a similar request ( creating over 20 unique legends using matplotlib ). There I showed that you can map the cycle of colors you need to plot your lines to a color map. You can use the same procedure to get a specific color for each pair of points.

You should choose the color map carefully, because color transitions along your line might appear drastic if the color map is colorful.

Alternatively, you can change the alpha of each line segment, ranging from 0 to 1.

Included in the code example below is a routine (highResPoints) to expand the number of points your random walk has, because if you have too few points, the transitions may seem drastic. This bit of code was inspired by another recent answer I provided: http://stackoverflow.com/a/8253729/717357

import numpy as np
import matplotlib.pyplot as plt

def highResPoints(x,y,factor=10):
    '''
    Take points listed in two vectors and return them at a higher
    resultion. Create at least factor*len(x) new points that include the
    original points and those spaced in between.

    Returns new x and y arrays as a tuple (x,y).
    '''

    # r is the distance spanned between pairs of points
    r = [0]
    for i in range(1,len(x)):
        dx = x[i]-x[i-1]
        dy = y[i]-y[i-1]
        r.append(np.sqrt(dx*dx+dy*dy))
    r = np.array(r)

    # rtot is a cumulative sum of r, it's used to save time
    rtot = []
    for i in range(len(r)):
        rtot.append(r[0:i].sum())
    rtot.append(r.sum())

    dr = rtot[-1]/(NPOINTS*RESFACT-1)
    xmod=[x[0]]
    ymod=[y[0]]
    rPos = 0 # current point on walk along data
    rcount = 1 
    while rPos < r.sum():
        x1,x2 = x[rcount-1],x[rcount]
        y1,y2 = y[rcount-1],y[rcount]
        dpos = rPos-rtot[rcount] 
        theta = np.arctan2((x2-x1),(y2-y1))
        rx = np.sin(theta)*dpos+x1
        ry = np.cos(theta)*dpos+y1
        xmod.append(rx)
        ymod.append(ry)
        rPos+=dr
        while rPos > rtot[rcount+1]:
            rPos = rtot[rcount+1]
            rcount+=1
            if rcount>rtot[-1]:
                break

    return xmod,ymod


#CONSTANTS
NPOINTS = 10
COLOR='blue'
RESFACT=10
MAP='winter' # choose carefully, or color transitions will not appear smoooth

# create random data
np.random.seed(101)
x = np.random.rand(NPOINTS)
y = np.random.rand(NPOINTS)

fig = plt.figure()
ax1 = fig.add_subplot(221) # regular resolution color map
ax2 = fig.add_subplot(222) # regular resolution alpha
ax3 = fig.add_subplot(223) # high resolution color map
ax4 = fig.add_subplot(224) # high resolution alpha

# Choose a color map, loop through the colors, and assign them to the color 
# cycle. You need NPOINTS-1 colors, because you'll plot that many lines 
# between pairs. In other words, your line is not cyclic, so there's 
# no line from end to beginning
cm = plt.get_cmap(MAP)
ax1.set_color_cycle([cm(1.*i/(NPOINTS-1)) for i in range(NPOINTS-1)])
for i in range(NPOINTS-1):
    ax1.plot(x[i:i+2],y[i:i+2])


ax1.text(.05,1.05,'Reg. Res - Color Map')
ax1.set_ylim(0,1.2)

# same approach, but fixed color and 
# alpha is scale from 0 to 1 in NPOINTS steps
for i in range(NPOINTS-1):
    ax2.plot(x[i:i+2],y[i:i+2],alpha=float(i)/(NPOINTS-1),color=COLOR)

ax2.text(.05,1.05,'Reg. Res - alpha')
ax2.set_ylim(0,1.2)

# get higher resolution data
xHiRes,yHiRes = highResPoints(x,y,RESFACT)
npointsHiRes = len(xHiRes)

cm = plt.get_cmap(MAP)

ax3.set_color_cycle([cm(1.*i/(npointsHiRes-1)) 
                     for i in range(npointsHiRes-1)])


for i in range(npointsHiRes-1):
    ax3.plot(xHiRes[i:i+2],yHiRes[i:i+2])

ax3.text(.05,1.05,'Hi Res - Color Map')
ax3.set_ylim(0,1.2)

for i in range(npointsHiRes-1):
    ax4.plot(xHiRes[i:i+2],yHiRes[i:i+2],
             alpha=float(i)/(npointsHiRes-1),
             color=COLOR)
ax4.text(.05,1.05,'High Res - alpha')
ax4.set_ylim(0,1.2)



fig.savefig('gradColorLine.png')
plt.show()

This figure shows the four cases:

enter image description here

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nice! I'll add this to my collection of code snippets. –  mathematical.coffee Dec 14 '11 at 14:07
    
@Yann: That's a nice feature Yann! I didn't knew about color map. But if you remove the line "ax.plot(x,y)" it gets better (less noise). Still, I can see 2 overlapping colors in each segment. Can you fix it? This kind of visualization can help a little if I use a 2 color map for example. However, what I was looking for was a smooth color transition even between points. Even better (but maybe asking too much) would be just one color but with an alpha factor for transparency smoothly changing as well. I just edited my question. Check out the image. –  PDRX Dec 15 '11 at 0:02
1  
@Yann Thank you! Your answer was a big help. One can see you're comfortable with matplotlib. The "highres" approach is clever. When I saw your first answer, I immediately though of creating aditional points to make the progressive grading as well, but you did it in a second! I was hopping there was some buit-in function in matplotlib that could handle the problem and save me from writting the code and having it always around! Guess I'll have to live with it. –  PDRX Dec 16 '11 at 1:08
    
if I set x = [1.0, 2.0, 3.0] and y = [1.0, 3.0, 8.0], this code will fail with Traceback (most recent call last): File ".../gradient", line 89, in <module>; xHiRes,yHiRes = highResPoints(x,y,RESFACT); File ".../gradient", line 67, in highResPoints; while rPos > rtot[rcount+1]: IndexError: list index out of range. How to fix this? –  shrx Nov 14 '14 at 12:47

Note that if you have many points, calling plt.plot for each line segment can be quite slow. It's more efficient to use a LineCollection object.

Using the colorline recipe you could do the following:

import matplotlib.pyplot as plt
import numpy as np
import matplotlib.collections as mcoll
import matplotlib.path as mpath

def colorline(
    x, y, z=None, cmap=plt.get_cmap('copper'), norm=plt.Normalize(0.0, 1.0),
        linewidth=3, alpha=1.0):
    """
    http://nbviewer.ipython.org/github/dpsanders/matplotlib-examples/blob/master/colorline.ipynb
    http://matplotlib.org/examples/pylab_examples/multicolored_line.html
    Plot a colored line with coordinates x and y
    Optionally specify colors in the array z
    Optionally specify a colormap, a norm function and a line width
    """

    # Default colors equally spaced on [0,1]:
    if z is None:
        z = np.linspace(0.0, 1.0, len(x))

    # Special case if a single number:
    if not hasattr(z, "__iter__"):  # to check for numerical input -- this is a hack
        z = np.array([z])

    z = np.asarray(z)

    segments = make_segments(x, y)
    lc = mcoll.LineCollection(segments, array=z, cmap=cmap, norm=norm,
                              linewidth=linewidth, alpha=alpha)

    ax = plt.gca()
    ax.add_collection(lc)

    return lc


def make_segments(x, y):
    """
    Create list of line segments from x and y coordinates, in the correct format
    for LineCollection: an array of the form numlines x (points per line) x 2 (x
    and y) array
    """

    points = np.array([x, y]).T.reshape(-1, 1, 2)
    segments = np.concatenate([points[:-1], points[1:]], axis=1)
    return segments

N = 10
np.random.seed(101)
x = np.random.rand(N)
y = np.random.rand(N)
fig, ax = plt.subplots()

path = mpath.Path(np.column_stack([x, y]))
verts = path.interpolated(steps=3).vertices
x, y = verts[:, 0], verts[:, 1]
z = np.linspace(0, 1, len(x))
colorline(x, y, z, cmap=plt.get_cmap('jet'), linewidth=2)

plt.show()

enter image description here

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Too long for a comment, so just wanted to confirm that LineCollection is a great deal faster than a for-loop over line subsegments.

the LineCollection method is a great deal faster in my hands.

# Setup
x = np.linspace(0,4*np.pi,1000)
y = np.sin(x)
MAP = 'cubehelix'
NPOINTS = len(x)

We'll test iterative plotting against LineCollection method above.

%%timeit -n1 -r1
# Using IPython notebook timing magics
fig = plt.figure()
ax1 = fig.add_subplot(111) # regular resolution color map
cm = plt.get_cmap(MAP)
for i in range(10):
    ax1.set_color_cycle([cm(1.*i/(NPOINTS-1)) for i in range(NPOINTS-1)])
    for i in range(NPOINTS-1):
        plt.plot(x[i:i+2],y[i:i+2])

1 loops, best of 1: 13.4 s per loop

%%timeit -n1 -r1 
fig = plt.figure()
ax1 = fig.add_subplot(111) # regular resolution color map
for i in range(10):
    colorline(x,y,cmap='cubehelix', linewidth=1)

1 loops, best of 1: 532 ms per loop

Upsampling your line for a better color gradient, as the currently selected answer provides, is still a good idea if you want a smooth gradient and you only have a few points.

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I've added my solution using pcolormesh Every line segment is drawn using a rectangle which is interpolating between colors at each end. So it truly is interpolating the color, but we have to pass a thickness of the line.

import numpy as np
import matplotlib.pyplot as plt

def colored_line(x, y, z=None, linewidth=1, MAP='jet'):
    # this uses pcolormesh to make interpolated rectangles
    xl = len(x)
    [xs, ys, zs] = [np.zeros((xl,2)), np.zeros((xl,2)), np.zeros((xl,2))]

    # z is the line length drawn or a list of vals to be plotted
    if z == None:
        z = [0]

    for i in range(xl-1):
        # make a vector to thicken our line points
        dx = x[i+1]-x[i]
        dy = y[i+1]-y[i]
        perp = np.array( [-dy, dx] )
        unit_perp = (perp/np.linalg.norm(perp))*linewidth

        # need to make 4 points for quadrilateral
        xs[i] = [x[i], x[i] + unit_perp[0] ]
        ys[i] = [y[i], y[i] + unit_perp[1] ]
        xs[i+1] = [x[i+1], x[i+1] + unit_perp[0] ]
        ys[i+1] = [y[i+1], y[i+1] + unit_perp[1] ]

        if len(z) == i+1:
            z.append(z[-1] + (dx**2+dy**2)**0.5)     
        # set z values
        zs[i] = [z[i], z[i] ] 
        zs[i+1] = [z[i+1], z[i+1] ]

    fig, ax = plt.subplots()
    cm = plt.get_cmap(MAP)
    ax.pcolormesh(xs, ys, zs, shading='gouraud', cmap=cm)
    plt.axis('scaled')
    plt.show()

# create random data
N = 10
np.random.seed(101)
x = np.random.rand(N)
y = np.random.rand(N)
colored_line(x, y, linewidth = .01)

enter image description here

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