Implements a disparity filter in Python, using graphs in NetworkX, based on multiscale backbone networks:
"Extracting the multiscale backbone of complex weighted networks"
M. Ángeles Serrano, Marián Boguña, Alessandro Vespignani
https://arxiv.org/pdf/0904.2389.pdf
The disparity filter exploits local heterogeneity and local correlations among weights to extract the network backbone by considering the relevant edges at all the scales present in the system. The methodology preserves an edge whenever its intensity is a statistically not compatible with respect to a null hypothesis of uniform randomness for at least one of the two nodes the edge is incident to, which ensures that small nodes in terms of strength are not neglected. As result, the disparity filter reduces the number of edges in the original network significantly keeping, at the same time, almost all the weight and a large fraction of nodes. As well, this filter preserves the cut-off of the degree distribution, the form of the weight distribution, and the clustering coefficient.
This project is similar to, albeit providing different features than:
If you are new to multiscale backbone analysis, think of this as analogous to centrality calculated on the edges of a graph rather than its nodes. In other words, consider this as a "dual" of the problem typically faced in social networks. By managing cuts through a process of iterating between measures of centrality and disparity respectively, one can scale a large, noisy graph into something more amenable for work with ontology -- especially as a way to clean up input for neural networks.
The code expects each node to have a required label attribute,
which is a string unique within all of the nodes in the graph. Each
edge is expected to have a weight attribute, a decimal in the
range of [0.0, 1.0] which represents the relative weight of that
edge's relationship.
After calculating the disparity metrics, each node get assigned a
strength attribute, which is the sum of its outbound edges'
weights. Each edge gets assigned the following attributes:
norm_weight: ratio of theedge[weight]/source_node[strength]alpha: disparity alpha metricalpha_ptile: percentile for alpha, compared across the graph
One important distinction is that this implementation comes from work in NLP and ontology, where graphs tend to become relatively "noisy" and there are many graphs generated through automation which need to be filtered. NLP applications had tended to reuse graph techniques from social graph analysis, such as connected components, centrality, cuts based on the relative degree of nodes -- while applications which combine NLP plus ontology tend to need information based on the edges.
In particular, this implementation focuses on directed graphs, and uses quantile analysis to adjust graph cuts. The original paper showed how to make cuts using the raw alpha values, which depended on manual (human) decisions. However, that is less than ideal for applications in machine learning, where more automation is typically required. Use of quantiles allows for a form of "normalization" for threshold values, so that cuts can be performed more consistently when automated.
This implementation also integrates support for working with neighborhood attention sets (NES) and other mechanisms for working with semantics and ontologies.
python3 -m venv venv
source venv/bin/activate
python3 -m pip install -U pip wheel
python3 -m pip install -r requirements.txt
The running default main() function:
python3 disparity.py
This will:
- generate a random graph (using a seed) of 100 nodes, each with < 10 edges
- calculate the significance (alpha) for the disparity filter
- calculate quantiles for alpha
- cut edges below the 50th percentile (median) for alpha
- cut nodes with degree < 2
graph: 100 nodes 489 edges
ptile alpha
0.00 0.0000
0.10 0.0305
0.20 0.0624
0.30 0.1027
0.40 0.1512
0.50 0.2159
0.60 0.3222
0.70 0.4821
0.80 0.7102
0.90 0.9998
filter: percentile 0.50, min alpha 0.2159, min degree 2
graph: 89 nodes 235 edges
In practice, adjust those thresholds as needed before making a cut on a graph. This mechanism provides a "dial" to adjust the scale of the multiscale backbone of the graph.
Please use the Issues section to ask questions or report any problems.