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I am trying to animate a scatter and bivariate gaussian distribution from a set of xy coordinates. I'll record the specific code that calls the scatter and distribution first and then how I measure the distribution afterwards.

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
import scipy.stats as sts
import matplotlib.animation as animation

''' Below is a section of the script that generates the scatter and contour '''

fig, ax = plt.subplots(figsize = (10,4))

def plotmvs(df, xlim=None, ylim=None, fig=fig, ax=ax):

    if xlim is None: xlim = datalimits(df['X'])
    if ylim is None: ylim = datalimits(df['Y'])

    PDFs = []
    for (group,gdf),color in zip(df.groupby('group'), ('red', 'blue')):

        ax.plot(*gdf[['X','Y']].values.T, '.', c=color, alpha = 0.5)

        kwargs = {
            'xlim': xlim,
            'ylim': ylim
        }
        X, Y, PDF = mvpdfs(gdf['X'].values, gdf['Y'].values, **kwargs)
        PDFs.append(PDF)

    PDF = PDFs[0] - PDFs[1]

    normPDF = PDF - PDF.min()
    normPDF = normPDF/normPDF.max()

    cfs = ax.contourf(X, Y, normPDF, levels=100, cmap='jet')

    return fig, ax

n = 10
time = [1]
d = ({      
    'A1_Y' : [10,20,15,20,25,40,50,60,61,65],                 
    'A1_X' : [15,10,15,20,25,25,30,40,60,61], 
    'A2_Y' : [10,13,17,10,20,24,29,30,33,40],                 
    'A2_X' : [10,13,15,17,18,19,20,21,26,30],
    'A3_Y' : [11,12,15,17,19,20,22,25,27,30],                 
    'A3_X' : [15,18,20,21,22,28,30,32,35,40], 
    'A4_Y' : [15,20,15,20,25,40,50,60,61,65],   
    'A4_X' : [16,20,15,30,45,30,40,10,11,15],                 
    'B1_Y' : [18,10,11,13,18,10,30,40,31,45],                 
    'B1_X' : [17,20,15,10,25,20,10,12,14,25], 
    'B2_Y' : [13,10,14,20,21,12,30,20,11,35],                 
    'B2_X' : [12,20,16,22,15,20,10,20,16,15],
    'B3_Y' : [15,20,15,20,25,10,20,10,15,25],                 
    'B3_X' : [18,15,13,20,21,10,20,10,11,15], 
    'B4_Y' : [19,12,15,18,14,19,13,12,11,18],   
    'B4_X' : [20,10,12,18,17,15,13,14,19,13],                                                                                    
     })        


tuples = [((t, k.split('_')[0][0], int(k.split('_')[0][1:]), k.split('_')[1]), v[i]) for k,v in d.items() for i,t in enumerate(time)]

df = pd.Series(dict(tuples)).unstack(-1)
df.index.names = ['time', 'group', 'id']

for time,tdf in df.groupby('time'):
    plotmvs(tdf)


'''MY ATTEMPT AT ANIMATING THE PLOT '''

def animate(i) :
    tdf.set_offsets([[tdf.iloc[0:,1][0+i][0], tdf.iloc[0:,0][0+i][0]], [tdf.iloc[0:,1][0+i][1], tdf.iloc[0:,0][0+i][1]], [tdf.iloc[0:,1][0+i][2], tdf.iloc[0:,0][0+i][2]], [tdf.iloc[0:,1][0+i][3], tdf.iloc[0:,0][0+i][3]], [tdf.iloc[0:,1][0+i][4], tdf.iloc[0:,0][0+i][4]]])
    normPDF = n[i,:,0,:].T
    cfs.set_data(X, Y, normPDF)

ani = animation.FuncAnimation(fig, animate, np.arange(0,10),# init_func = init,
                              interval = 10, blit = False)

A full working code on how the distribution is generated and plotted using a single frame

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
import scipy.stats as sts
import matplotlib.animation as animation

def datalimits(*data, pad=.15):
    dmin,dmax = min(d.min() for d in data), max(d.max() for d in data)
    spad = pad*(dmax - dmin)
    return dmin - spad, dmax + spad

def rot(theta):
    theta = np.deg2rad(theta)
    return np.array([
        [np.cos(theta), -np.sin(theta)],
        [np.sin(theta), np.cos(theta)]
    ])

def getcov(radius=1, scale=1, theta=0):
    cov = np.array([
        [radius*(scale + 1), 0],
        [0, radius/(scale + 1)]
    ])

    r = rot(theta)
    return r @ cov @ r.T

def mvpdf(x, y, xlim, ylim, radius=1, velocity=0, scale=0, theta=0):

    X,Y = np.meshgrid(np.linspace(*xlim), np.linspace(*ylim))

    XY = np.stack([X, Y], 2)

    x,y = rot(theta) @ (velocity/2, 0) + (x, y)

    cov = getcov(radius=radius, scale=scale, theta=theta)

    PDF = sts.multivariate_normal([x, y], cov).pdf(XY)

    return X, Y, PDF

def mvpdfs(xs, ys, xlim, ylim, radius=None, velocity=None, scale=None, theta=None):
    PDFs = []
    for i,(x,y) in enumerate(zip(xs,ys)):
        kwargs = {
            'xlim': xlim,
            'ylim': ylim
        }
        X, Y, PDF = mvpdf(x, y,**kwargs)
        PDFs.append(PDF)

    return X, Y, np.sum(PDFs, axis=0)

fig, ax = plt.subplots(figsize = (10,4))

def plotmvs(df, xlim=None, ylim=None, fig=fig, ax=ax):

    if xlim is None: xlim = datalimits(df['X'])
    if ylim is None: ylim = datalimits(df['Y'])

    PDFs = []
    for (group,gdf),color in zip(df.groupby('group'), ('red', 'blue')):

        #Animate this scatter
        ax.plot(*gdf[['X','Y']].values.T, '.', c=color, alpha = 0.5)

        kwargs = {
            'xlim': xlim,
            'ylim': ylim
        }
        X, Y, PDF = mvpdfs(gdf['X'].values, gdf['Y'].values, **kwargs)
        PDFs.append(PDF)

    PDF = PDFs[0] - PDFs[1]

    normPDF = PDF - PDF.min()
    normPDF = normPDF/normPDF.max()

    #Animate this contour
    cfs = ax.contourf(X, Y, normPDF, levels=100, cmap='jet')

    return fig, ax

n = 10

time = [1]
d = ({      
    'A1_Y' : [10,20,15,20,25,40,50,60,61,65],                 
    'A1_X' : [15,10,15,20,25,25,30,40,60,61], 
    'A2_Y' : [10,13,17,10,20,24,29,30,33,40],                 
    'A2_X' : [10,13,15,17,18,19,20,21,26,30],
    'A3_Y' : [11,12,15,17,19,20,22,25,27,30],                 
    'A3_X' : [15,18,20,21,22,28,30,32,35,40], 
    'A4_Y' : [15,20,15,20,25,40,50,60,61,65],   
    'A4_X' : [16,20,15,30,45,30,40,10,11,15],                 
    'B1_Y' : [18,10,11,13,18,10,30,40,31,45],                 
    'B1_X' : [17,20,15,10,25,20,10,12,14,25], 
    'B2_Y' : [13,10,14,20,21,12,30,20,11,35],                 
    'B2_X' : [12,20,16,22,15,20,10,20,16,15],
    'B3_Y' : [15,20,15,20,25,10,20,10,15,25],                 
    'B3_X' : [18,15,13,20,21,10,20,10,11,15], 
    'B4_Y' : [19,12,15,18,14,19,13,12,11,18],   
    'B4_X' : [20,10,12,18,17,15,13,14,19,13],                                                                                   
     })        

tuples = [((t, k.split('_')[0][0], int(k.split('_')[0][1:]), k.split('_')[1]), v[i]) for k,v in d.items() for i,t in enumerate(time)]

df = pd.Series(dict(tuples)).unstack(-1)
df.index.names = ['time', 'group', 'id']

for time,tdf in df.groupby('time'):
    plotmvs(tdf)

I essentially want to animate this code by iterating over each row of xy coordinates.

  • Some suggestions that may help others help you: mcve, PEP20, and PEP8. Especially the "m" of mcve. – djvg Jan 7 at 16:23
  • @Dennis. Thankyou. I've tried to segment the code into critical parts. If this is too confusing I'll attempt to ask a less similar question – user9410826 Jan 8 at 0:12
  • Does the answer below work for you? – djvg Jan 10 at 8:48
  • Thanks @ djvg. I'm just trying to get it going with my actual dataset. I need to adjust the data limits. I need the xlim to be 3000, 3200 and the ylim to be -5800, -6000. Is this possible? – user9410826 Jan 10 at 9:38
  • I've accepted the answer @djvg. Thanks for looking at this. I understand the question was pretty involved without the adjusting the datalimits – user9410826 Jan 13 at 22:14
4
+50

Here's a very quick and dirty modification of the OP's code, fixing the scatter animation and adding (a form of) contour animation.

Basically, you start by creating the artists for your animation (in this case Line2D objects, as returned by plot()). Subsequently, you create an update function (and, optionally, an initialization function). In that function, you update the existing artists. I think the example in the matplotlib docs explains it all.

In this case, I modified the OP's plotmvs function to be used as the update function (instead of the OP's proposed animate function).

The QuadContourSet returned by contourf (i.e. your cfs) cannot be used as an artist in itself, but you can make it work using cfs.collections (props to this SO answer). However, you still need to create a new contour plot and remove the old one, instead of just updating the contour data. Personally I would prefer a lower level approach: try to get the contour-data without calling contourf, then initialize and update the contour lines just like you do for the scatter.

Nevertheless, the approach above is implemented in the OP's code below (just copy, paste, and run):

import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
import scipy.stats as sts
from matplotlib.animation import FuncAnimation

# quick and dirty override of datalimits(), to get a fixed contour-plot size
DATA_LIMITS = [0, 70]

def datalimits(*data, pad=.15):
    # dmin,dmax = min(d.min() for d in data), max(d.max() for d in data)
    # spad = pad*(dmax - dmin)
    return DATA_LIMITS  # dmin - spad, dmax + spad

def rot(theta):
    theta = np.deg2rad(theta)
    return np.array([
        [np.cos(theta), -np.sin(theta)],
        [np.sin(theta), np.cos(theta)]
    ])

def getcov(radius=1, scale=1, theta=0):
    cov = np.array([
        [radius*(scale + 1), 0],
        [0, radius/(scale + 1)]
    ])

    r = rot(theta)
    return r @ cov @ r.T

def mvpdf(x, y, xlim, ylim, radius=1, velocity=0, scale=0, theta=0):

    X,Y = np.meshgrid(np.linspace(*xlim), np.linspace(*ylim))

    XY = np.stack([X, Y], 2)

    x,y = rot(theta) @ (velocity/2, 0) + (x, y)

    cov = getcov(radius=radius, scale=scale, theta=theta)

    PDF = sts.multivariate_normal([x, y], cov).pdf(XY)

    return X, Y, PDF

def mvpdfs(xs, ys, xlim, ylim, radius=None, velocity=None, scale=None, theta=None):
    PDFs = []
    for i,(x,y) in enumerate(zip(xs,ys)):
        kwargs = {
            'xlim': xlim,
            'ylim': ylim
        }
        X, Y, PDF = mvpdf(x, y,**kwargs)
        PDFs.append(PDF)

    return X, Y, np.sum(PDFs, axis=0)


fig, ax = plt.subplots(figsize = (10,4))
ax.set_xlim(DATA_LIMITS)
ax.set_ylim(DATA_LIMITS)

# Initialize empty lines for the scatter (increased marker size to make them more visible)
line_a, = ax.plot([], [], '.', c='red', alpha = 0.5, markersize=20, animated=True)
line_b, = ax.plot([], [], '.', c='blue', alpha = 0.5, markersize=20, animated=True)
cfs = None

# Modify the plotmvs function so it updates the lines 
# (might as well rename the function to "update")
def plotmvs(tdf, xlim=None, ylim=None):
    global cfs  # as noted: quick and dirty...
    if cfs:
        for tp in cfs.collections:
            # Remove the existing contours
            tp.remove()

    # Get the data frame for time t
    df = tdf[1]

    if xlim is None: xlim = datalimits(df['X'])
    if ylim is None: ylim = datalimits(df['Y'])

    PDFs = []

    for (group, gdf), group_line in zip(df.groupby('group'), (line_a, line_b)):

        #Animate this scatter
        #ax.plot(*gdf[['X','Y']].values.T, '.', c=color, alpha = 0.5)

        # Update the scatter line data
        group_line.set_data(*gdf[['X','Y']].values.T)

        kwargs = {
            'xlim': xlim,
            'ylim': ylim
        }
        X, Y, PDF = mvpdfs(gdf['X'].values, gdf['Y'].values, **kwargs)
        PDFs.append(PDF)


    PDF = PDFs[0] - PDFs[1]

    normPDF = PDF - PDF.min()
    normPDF = normPDF / normPDF.max()

    # Plot a new contour
    cfs = ax.contourf(X, Y, normPDF, levels=100, cmap='jet')

    # Return the artists (the trick is to return cfs.collections instead of cfs)
    return cfs.collections + [line_a, line_b]

n = 10
time = range(n)  # assuming n represents the length of the time vector...
d = ({
    'A1_Y' : [10,20,15,20,25,40,50,60,61,65],
    'A1_X' : [15,10,15,20,25,25,30,40,60,61],
    'A2_Y' : [10,13,17,10,20,24,29,30,33,40],
    'A2_X' : [10,13,15,17,18,19,20,21,26,30],
    'A3_Y' : [11,12,15,17,19,20,22,25,27,30],
    'A3_X' : [15,18,20,21,22,28,30,32,35,40],
    'A4_Y' : [15,20,15,20,25,40,50,60,61,65],
    'A4_X' : [16,20,15,30,45,30,40,10,11,15],
    'B1_Y' : [18,10,11,13,18,10,30,40,31,45],
    'B1_X' : [17,20,15,10,25,20,10,12,14,25],
    'B2_Y' : [13,10,14,20,21,12,30,20,11,35],
    'B2_X' : [12,20,16,22,15,20,10,20,16,15],
    'B3_Y' : [15,20,15,20,25,10,20,10,15,25],
    'B3_X' : [18,15,13,20,21,10,20,10,11,15],
    'B4_Y' : [19,12,15,18,14,19,13,12,11,18],
    'B4_X' : [20,10,12,18,17,15,13,14,19,13],
     })

tuples = [((t, k.split('_')[0][0], int(k.split('_')[0][1:]), k.split('_')[1]), v[i]) 
          for k,v in d.items() for i,t in enumerate(time)]

df = pd.Series(dict(tuples)).unstack(-1)
df.index.names = ['time', 'group', 'id']

# Use the modified plotmvs as the update function, and supply the data frames
interval_ms = 200
delay_ms = 1000
ani = FuncAnimation(fig, plotmvs, frames=df.groupby('time'),
                    blit=True, interval=interval_ms, repeat_delay=delay_ms)

# Start the animation
plt.show()
  • not really “just copy, paste, and run” – Walter Tross Jan 8 at 22:06
  • TypeError: len() of unsized object where the object is self.levels in matplotlib/contour.py called from cfs = ax.contourf(X, Y, normPDF, levels=100, cmap='jet') – Walter Tross Jan 8 at 22:20
  • @WalterTross: cannot test this right now, but could it be that you are using an older version of matplotlib that does not support integer values for the 'levels' argument (e.g v2.1.2)? – djvg Jan 8 at 22:59
  • @WalterTross: The specific line raising your error is a verbatim copy from the OP's example. Just tested the code above, and, as I suspected, your TypeError appears when using the old matplotlib=2.1.2. The code runs as intended on windows 10 with python=3.6.5, matplotlib=3.0.2, numpy=1.15.2, scipy=1.1.0, pandas=0.23.4. A quick fix for matplotlib=2.1.2 would be to pass in a list for the levels, but you would have to figure out the values yourself. Easiest would be to upgrade matplotlib. – djvg Jan 9 at 7:13
  • @WalterTross: if you need to use Python 2.7, I think matplotlib 2.2.3 LTS (long term support) also supports integer values for the levels argument (contourf docs). – djvg Jan 9 at 7:18

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