# How can I improve my paw detection?

After my previous question on finding toes within each paw, I started loading up other measurements to see how it would hold up. Unfortunately, I quickly ran into a problem with one of the preceding steps: recognizing the paws.

You see, my proof of concept basically took the maximal pressure of each sensor over time and would start looking for the sum of each row, until it finds on that != 0.0. Then it does the same for the columns and as soon as it finds more than 2 rows with that are zero again. It stores the minimal and maximal row and column values to some index.

As you can see in the figure, this works quite well in most cases. However, there are a lot of downsides to this approach (other than being very primitive):

• Humans can have 'hollow feet' which means there are several empty rows within the footprint itself. Since I feared this could happen with (large) dogs too, I waited for at least 2 or 3 empty rows before cutting off the paw.

This creates a problem if another contact made in a different column before it reaches several empty rows, thus expanding the area. I figure I could compare the columns and see if they exceed a certain value, they must be separate paws.

• The problem gets worse when the dog is very small or walks at a higher pace. What happens is that the front paw's toes are still making contact, while the hind paw's toes just start to make contact within the same area as the front paw!

With my simple script, it won't be able to split these two, because it would have to determine which frames of that area belong to which paw, while currently I would only have to look at the maximal values over all frames.

Examples of where it starts going wrong:

So now I'm looking for a better way of recognizing and separating the paws (after which I'll get to the problem of deciding which paw it is!).

Update:

I've been tinkering to get Joe's (awesome!) answer implemented, but I'm having difficulties extracting the actual paw data from my files.

The coded_paws shows me all the different paws, when applied to the maximal pressure image (see above). However, the solution goes over each frame (to separate overlapping paws) and sets the four Rectangle attributes, such as coordinates or height/width.

I can't figure out how to take these attributes and store them in some variable that I can apply to the measurement data. Since I need to know for each paw, what its location is during which frames and couple this to which paw it is (front/hind, left/right).

So how can I use the Rectangles attributes to extract these values for each paw?

I have the measurements I used in the question setup in my public Dropbox folder (example 1, example 2, example 3). For anyone interested I also set up a blog to keep you up to date :-)

• Seems like you would have to turn away from the row/column algorithm an you're limiting useful information. Nov 3, 2010 at 22:21
• Wow! Cat control software?
– alxx
Nov 10, 2010 at 8:34
• It's dog data actually @alxx ;-) But yeah, it will be used to diagnose them! Nov 10, 2010 at 8:37
• Why? (nevermind, it's more fun not knowing...) Nov 14, 2010 at 23:29

If you're just wanting (semi) contiguous regions, there's already an easy implementation in Python: SciPy's ndimage.morphology module. This is a fairly common image morphology operation.

Basically, you have 5 steps:

``````def find_paws(data, smooth_radius=5, threshold=0.0001):
thresh = data > threshold
filled = sp.ndimage.morphology.binary_fill_holes(thresh)
coded_paws, num_paws = sp.ndimage.label(filled)
data_slices = sp.ndimage.find_objects(coded_paws)
return object_slices
``````
1. Blur the input data a bit to make sure the paws have a continuous footprint. (It would be more efficient to just use a larger kernel (the `structure` kwarg to the various `scipy.ndimage.morphology` functions) but this isn't quite working properly for some reason...)

2. Threshold the array so that you have a boolean array of places where the pressure is over some threshold value (i.e. `thresh = data > value`)

3. Fill any internal holes, so that you have cleaner regions (`filled = sp.ndimage.morphology.binary_fill_holes(thresh)`)

4. Find the separate contiguous regions (`coded_paws, num_paws = sp.ndimage.label(filled)`). This returns an array with the regions coded by number (each region is a contiguous area of a unique integer (1 up to the number of paws) with zeros everywhere else)).

5. Isolate the contiguous regions using `data_slices = sp.ndimage.find_objects(coded_paws)`. This returns a list of tuples of `slice` objects, so you could get the region of the data for each paw with `[data[x] for x in data_slices]`. Instead, we'll draw a rectangle based on these slices, which takes slightly more work.

The two animations below show your "Overlapping Paws" and "Grouped Paws" example data. This method seems to be working perfectly. (And for whatever it's worth, this runs much more smoothly than the GIF images below on my machine, so the paw detection algorithm is fairly fast...)

Here's a full example (now with much more detailed explanations). The vast majority of this is reading the input and making an animation. The actual paw detection is only 5 lines of code.

``````import numpy as np
import scipy as sp
import scipy.ndimage

import matplotlib.pyplot as plt
from matplotlib.patches import Rectangle

def animate(input_filename):
"""Detects paws and animates the position and raw data of each frame
in the input file"""
# With matplotlib, it's much, much faster to just update the properties
# of a display object than it is to create a new one, so we'll just update
# the data and position of the same objects throughout this animation...

infile = paw_file(input_filename)

# Since we're making an animation with matplotlib, we need
plt.ion()
fig = plt.figure()
fig.suptitle(input_filename)

# Make an image based on the first frame that we'll update later
# (The first frame is never actually displayed)
im = ax.imshow(infile.next()[1])

# Make 4 rectangles that we can later move to the position of each paw
rects = [Rectangle((0,0), 1,1, fc='none', ec='red') for i in range(4)]

title = ax.set_title('Time 0.0 ms')

# Process and display each frame
for time, frame in infile:
paw_slices = find_paws(frame)

# Hide any rectangles that might be visible
[rect.set_visible(False) for rect in rects]

# Set the position and size of a rectangle for each paw and display it
for slice, rect in zip(paw_slices, rects):
dy, dx = slice
rect.set_xy((dx.start, dy.start))
rect.set_width(dx.stop - dx.start + 1)
rect.set_height(dy.stop - dy.start + 1)
rect.set_visible(True)

# Update the image data and title of the plot
title.set_text('Time %0.2f ms' % time)
im.set_data(frame)
im.set_clim([frame.min(), frame.max()])
fig.canvas.draw()

"""Detects and isolates contiguous regions in the input array"""
# Blur the input data a bit so the paws have a continous footprint
# Threshold the blurred data (this needs to be a bit > 0 due to the blur)
thresh = data > threshold
# Fill any interior holes in the paws to get cleaner regions...
filled = sp.ndimage.morphology.binary_fill_holes(thresh)
# Label each contiguous paw
coded_paws, num_paws = sp.ndimage.label(filled)
# Isolate the extent of each paw
data_slices = sp.ndimage.find_objects(coded_paws)
return data_slices

def paw_file(filename):
"""Returns a iterator that yields the time and data in each frame
The infile is an ascii file of timesteps formatted similar to this:

Frame 0 (0.00 ms)
0.0 0.0 0.0
0.0 0.0 0.0

Frame 1 (0.53 ms)
0.0 0.0 0.0
0.0 0.0 0.0
...
"""
with open(filename) as infile:
while True:
try:
yield time, data
except StopIteration:
break

"""Reads a frame from the infile."""
data = []
while True:
line = infile.next().strip().split()
if line == []:
break
data.append(line)
return time, np.array(data, dtype=np.float)

if __name__ == '__main__':
animate('Overlapping paws.bin')
animate('Grouped up paws.bin')
animate('Normal measurement.bin')
``````

Update: As far as identifying which paw is in contact with the sensor at what times, the simplest solution is to just do the same analysis, but use all of the data at once. (i.e. stack the input into a 3D array, and work with it, instead of the individual time frames.) Because SciPy's ndimage functions are meant to work with n-dimensional arrays, we don't have to modify the original paw-finding function at all.

``````# This uses functions (and imports) in the previous code example!!
def paw_regions(infile):
# Read in and stack all data together into a 3D array
data, time = [], []
for t, frame in paw_file(infile):
time.append(t)
data.append(frame)
data = np.dstack(data)
time = np.asarray(time)

# Find and label the paw impacts

# Sort by time of initial paw impact... This way we can determine which
# paws are which relative to the first paw with a simple modulo 4.
# (Assuming a 4-legged dog, where all 4 paws contacted the sensor)
data_slices.sort(key=lambda dat_slice: dat_slice[2].start)

# Plot up a simple analysis
fig = plt.figure()
annotate_paw_prints(time, data, data_slices, ax=ax1)
plot_paw_impacts(time, data_slices, ax=ax2)
fig.suptitle(infile)

def plot_paw_impacts(time, data_slices, ax=None):
if ax is None:
ax = plt.gca()

# Group impacts by paw...
for i, dat_slice in enumerate(data_slices):
dx, dy, dt = dat_slice
paw = i%4 + 1
# Draw a bar over the time interval where each paw is in contact
ax.barh(bottom=paw, width=time[dt].ptp(), height=0.2,
left=time[dt].min(), align='center', color='red')
ax.set_yticks(range(1, 5))
ax.set_yticklabels(['Paw 1', 'Paw 2', 'Paw 3', 'Paw 4'])
ax.set_xlabel('Time (ms) Since Beginning of Experiment')
ax.yaxis.grid(True)
ax.set_title('Periods of Paw Contact')

def annotate_paw_prints(time, data, data_slices, ax=None):
if ax is None:
ax = plt.gca()

# Display all paw impacts (sum over time)
ax.imshow(data.sum(axis=2).T)

# Annotate each impact with which paw it is
# (Relative to the first paw to hit the sensor)
x, y = [], []
for i, region in enumerate(data_slices):
dx, dy, dz = region
# Get x,y center of slice...
x0 = 0.5 * (dx.start + dx.stop)
y0 = 0.5 * (dy.start + dy.stop)
x.append(x0); y.append(y0)

# Annotate the paw impacts
ax.annotate('Paw %i' % (i%4 +1), (x0, y0),
color='red', ha='center', va='bottom')

# Plot line connecting paw impacts
ax.plot(x,y, '-wo')
ax.axis('image')
ax.set_title('Order of Steps')
``````

• I can't even begin to explain how awesome you answer is! Nov 4, 2010 at 16:03
• @Ivo: Yes, I would enjoy upvoting Joe some more too :) but should I start a new question, or perhaps @Joe, if you would, answer here? stackoverflow.com/questions/2546780/… Nov 4, 2010 at 20:26
• I actually just dumped out .png's, and did a `convert *.png output.gif`. I've certainly had imagemagick bring my machine to its knees before, though it worked fine for this example. In the past, I've used this script: svn.effbot.python-hosting.com/pil/Scripts/gifmaker.py to directly write an animated gif from python without saving the individual frames. Hope that helps! I'll post an example at the question @unutbu mentioned. Nov 4, 2010 at 20:59
• Thanks for the information, @Joe. Part of my problem was neglecting to use `bbox_inches='tight'` in the `plt.savefig`, the other was impatience :) Nov 4, 2010 at 23:34
• Holy cow, I just have to say wow at how great this answer is. Nov 15, 2010 at 1:05

I'm no expert in image detection, and I don't know Python, but I'll give it a whack...

To detect individual paws, you should first only select everything with a pressure greater than some small threshold, very close to no pressure at all. Every pixel/point that is above this should be "marked." Then, every pixel adjacent to all "marked" pixels becomes marked, and this process is repeated a few times. Masses that are totally connected would be formed, so you have distinct objects. Then, each "object" has a minimum and maximum x and y value, so bounding boxes can be packed neatly around them.

Pseudocode:

`(MARK) ALL PIXELS ABOVE (0.5)`

`(MARK) ALL PIXELS (ADJACENT) TO (MARK) PIXELS`

`REPEAT (STEP 2) (5) TIMES`

`SEPARATE EACH TOTALLY CONNECTED MASS INTO A SINGLE OBJECT`

`MARK THE EDGES OF EACH OBJECT, AND CUT APART TO FORM SLICES.`