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<head><title>1.1.1.0 degs_to_activity_overlap.py</title>
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<h5 class="subsubsectionHead"><a
id="x13-120001.1.1"></a><span
class="cmtt-10x-x-109">degs</span><span
class="cmtt-10x-x-109">_to</span><span
class="cmtt-10x-x-109">_activity</span><span
class="cmtt-10x-x-109">_overlap.py</span></h5>
<!--l. 4--><p class="noindent" ><span
class="cmbx-10x-x-109">NAME</span>
<!--l. 4--><p class="indent" > <span
class="cmbx-10x-x-109">degs</span><span
class="cmbx-10x-x-109">_to</span><span
class="cmbx-10x-x-109">_activity</span><span
class="cmbx-10x-x-109">_overlap.py </span>- compute the activity and the total
(overlapping) degree of all the nodes of a multiplex.
<!--l. 4--><p class="noindent" ><span
class="cmbx-10x-x-109">SYNOPSYS</span>
<!--l. 4--><p class="indent" > <span
class="cmbx-10x-x-109">degs</span><span
class="cmbx-10x-x-109">_to</span><span
class="cmbx-10x-x-109">_activity</span><span
class="cmbx-10x-x-109">_overlap.py </span><span
class="cmmi-10x-x-109"><</span><span
class="cmitt-10x-x-109">degree</span><span
class="cmitt-10x-x-109">_vectors</span><span
class="cmmi-10x-x-109">></span>
<!--l. 14--><p class="noindent" ><span
class="cmbx-10x-x-109">DESCRIPTION</span>
<!--l. 14--><p class="indent" > Take a file which contains, on the n-th line, the degrees at each layer of the
n-th node, (e.g., the result of the script <span
class="cmtt-10x-x-109">node</span><span
class="cmtt-10x-x-109">_degree</span><span
class="cmtt-10x-x-109">_vectors.py</span>), in the
format:
<!--l. 14--><p class="indent" >   <span
class="cmti-10x-x-109">noden</span><span
class="cmti-10x-x-109">_deg</span><span
class="cmti-10x-x-109">_lay1 noden</span><span
class="cmti-10x-x-109">_deg</span><span
class="cmti-10x-x-109">_lay2 ... noden</span><span
class="cmti-10x-x-109">_deg</span><span
class="cmti-10x-x-109">_layM</span>
<!--l. 14--><p class="noindent" >and compute the activity (i.e., the number of layers in which a node is not
isolated) and the total (overlapping) degree of each node.
<!--l. 26--><p class="noindent" ><span
class="cmbx-10x-x-109">OUTPUT</span>
<!--l. 26--><p class="indent" > The program prints on <span
class="cmtt-10x-x-109">stdout </span>a list of lines, where the n-th line contains the
activity and the total degree of the n-th nodem in the format:
<!--l. 26--><p class="indent" >   <span
class="cmti-10x-x-109">noden</span><span
class="cmti-10x-x-109">_activity noden</span><span
class="cmti-10x-x-109">_tot</span><span
class="cmti-10x-x-109">_deg</span>
<!--l. 26--><p class="noindent" >As usual, the program assumes that node IDs start from zero and proceed
sequentially, without gaps, i.e., if a node ID is not present in any of the layer
files given as input, the program considers it as being isolated on all the
layers.
<!--l. 28--><p class="noindent" ><span
class="cmbx-10x-x-109">REFERENCE</span>
<!--l. 28--><p class="indent" > V. Nicosia, V. Latora, “Measuring and modeling correlations in multiplex
networks”, <span
class="cmti-10x-x-109">Phys. Rev. E </span><span
class="cmbx-10x-x-109">92</span>, 032805 (2015).
<!--l. 28--><p class="indent" > Link to paper: <a
href="http://journals.aps.org/pre/abstract/10.1103/PhysRevE.92.032805" class="url" ><span
class="cmtt-10x-x-109">http://journals.aps.org/pre/abstract/10.1103/PhysRevE.92.032805</span></a>
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