# Drawing multilevel graphs with networkx?

I'm trying to visualize a few graphs whose nodes represent different objects. I want to create an image that looks like the one here:

Basically, I need a 3D plot and the ability to draw edges between nodes on the same level or nodes on different levels.

-
I noticed the tag saying python, but do you have any other packages or add-ons? It would be much easier to help if you told us what tools you have to work with. –  HardcoreBro Jul 19 at 17:33
I have pydot, numpy, and matplotlib as well. I'm also running Python 2.7 if that helps. –  Danny Jul 19 at 17:42

This answer below may not be a complete solution, but is a working demo for rendering 3D graphs using networkx. networkx as such cannot render 3D graphs. We will have to install mayavi for that to happen.

``````import networkx as nx
import matplotlib.pyplot as plt
import numpy as np
from mayavi import mlab

import random

def draw_graph3d(graph, graph_colormap='winter', bgcolor = (1, 1, 1),
node_size=0.03,
edge_color=(0.8, 0.8, 0.8), edge_size=0.002,
text_size=0.008, text_color=(0, 0, 0)):

H=nx.Graph()

for node, edges in graph.items():
for edge, val in edges.items():
if val == 1:

G=nx.convert_node_labels_to_integers(H)

graph_pos=nx.spring_layout(G, dim=3)

# numpy array of x,y,z positions in sorted node order
xyz=np.array([graph_pos[v] for v in sorted(G)])

# scalar colors
scalars=np.array(G.nodes())+5
mlab.figure(1, bgcolor=bgcolor)
mlab.clf()

#----------------------------------------------------------------------------
# the x,y, and z co-ordinates are here
# manipulate them to obtain the desired projection perspective
pts = mlab.points3d(xyz[:,0], xyz[:,1], xyz[:,2],
scalars,
scale_factor=node_size,
scale_mode='none',
colormap=graph_colormap,
resolution=20)
#----------------------------------------------------------------------------

for i, (x, y, z) in enumerate(xyz):
label = mlab.text(x, y, str(i), z=z,
width=text_size, name=str(i), color=text_color)

pts.mlab_source.dataset.lines = np.array(G.edges())
mlab.pipeline.surface(tube, color=edge_color)

mlab.show() # interactive window

# create tangled hypercube
def make_graph(nodes):

graph[i1][i2] = 1
graph[i2][i1] = 1

n = len(nodes)

if n == 1: return {nodes[0]:{}}

nodes1 = nodes[0:n/2]
nodes2 = nodes[n/2:]
G1 = make_graph(nodes1)
G2 = make_graph(nodes2)

# merge G1 and G2 into a single graph
G = dict(G1.items() + G2.items())

random.shuffle(nodes1)
random.shuffle(nodes2)
for i in range(len(nodes1)):

return G

# graph example
nodes = range(10)
graph = make_graph(nodes)
draw_graph3d(graph)
``````

This code was modified from one of the examples here. Please post the code in this case, when you succeed in reaching the objective.

-
Please also have a look at page 19 of this document -- cs.brown.edu/~rt/gdhandbook/chapters/force-directed.pdf . The illustration clearly have the same structure like your objective visualization, and I guess this was rendered with networkx and mayavi. –  Vikram Jul 25 at 12:26