Skip to content

PMEAL/porespy

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

image image

What is PoreSpy?

PoreSpy is a collection of image analysis tools used to extract information from 3D images of porous materials (typically obtained from X-ray tomography). There are many packages that offer generalized image analysis tools (i.e Skimage and Scipy.NDimage in the Python environment, ImageJ, MatLab's Image Processing Toolbox), but they all require building up complex scripts or macros to accomplish tasks of specific use to porous media. The aim of PoreSpy is to provide a set of pre-written tools for all the common porous media measurements. For instance, it's possible to perform a mercury intrusion simulation with a single function call (e.g. porespy.filters.porosimetry).

PoreSpy relies heavily on scipy.ndimage and scikit-image also known as skimage. The former contains an assortment of general image analysis tools such as image morphology filters, while the latter offers more complex but still general functions such as watershed segmentation. PoreSpy does not duplicate any of these general functions so you will also have to install and learn how to use them to get the most from PoreSpy. The functions in PoreSpy are generally built up using several of the general functions offered by skimage and scipy. There are a few functions in PoreSpy that are implemented natively, but only when necessary.

Capabilities

PoreSpy consists of the following modules:

  • generators: Routines for generating artificial images of porous materials useful for testing and illustration
  • filters: Functions that accept an image and return an altered image
  • metrics: Tools for quantifying properties of images
  • networks: Algorithms and tools for analyzing images as pore networks
  • simulations: Physical simulations on images including drainage
  • visualization: Helper functions for creating useful views of the image
  • io: Functions for outputting image data in various formats for use in common software
  • tools: Various useful tools for working with images

Gallery

Cite as

Gostick J, Khan ZA, Tranter TG, Kok MDR, Agnaou M, Sadeghi MA, Jervis R. PoreSpy: A Python Toolkit for Quantitative Analysis of Porous Media Images. Journal of Open Source Software, 2019. doi:10.21105/joss.01296

Installation

For detailed and up to date installation instructions, see here

Contributing

If you think you may be interested in contributing to PoreSpy and wish to both use and edit the source code, then you should clone the repository to your local machine, and install it using the following PIP command:

pip install -e "C:\path\to\the\local\files\"

For information about contributing, refer to the contributors guide

Acknowledgements

PoreSpy is grateful to CANARIE for their generous funding over the past few years. We would also like to acknowledge the support of NSERC of Canada for funding many of the student that have contributed to PoreSpy since it's inception in 2014.

Examples

The following code snippets illustrate generating a 2D image, applying several filters, and calculating some common metrics. A set of examples is included in this repo, and can be browsed here.

Generating an image

PoreSpy offers several ways to generate artificial images, for quick testing and developmnet of work flows, instead of dealing with reading/writing/storing of large tomograms.

import porespy as ps
import matplotlib.pyplot as plt
im = ps.generators.blobs(shape=[500, 500], porosity=0.6, blobiness=2)
plt.imshow(im)

Applying filters

A common filter to apply is the local thickness, which replaces every voxel with the radius of a sphere that overlaps it. Analysis of the histogram of the voxel values provides information about the pore size distribution.

lt = ps.filters.local_thickness(im)
plt.imshow(lt)

A less common filter is the application of chords that span the pore space in a given direction. It is possible to gain information about anisotropy of the material by looking at the distributions of chords lengths in each principle direction.

cr = ps.filters.apply_chords(im)
cr = ps.filters.flood(cr, mode='size')
plt.imshow(cr)

Calculating metrics

The metrics sub-module contains several common functions that analyze binary tomogram directly. Examples are simple porosity, as well as two-point correlation function.

data = ps.metrics.two_point_correlation_fft(im)
fig = plt.plot(*data, 'bo-')
plt.ylabel('probability')
plt.xlabel('correlation length [voxels]')

The metrics sub-module also contains a suite of functions that produce plots based on values in images that have passed through a filter, such as local thickness.

mip = ps.filters.porosimetry(im)
data = ps.metrics.pore_size_distribution(mip, log=False)
plt.imshow(mip)
# Now show intrusion curve
plt.plot(data.R, data.cdf, 'bo-')
plt.xlabel('invasion size [voxels]')
plt.ylabel('volume fraction invaded [voxels]')