Currently I have created a color map based on the distance of the nodes in the network to a specific target. The one thing I am not being able to do is a color bar. I would like the color bar to show me how much time the color indicates.

**The time data is in data['time'].**

Each color will indicate how long it will take to go from the node to the target. I have defined the speed of the car.

For example, a color bar that ranges from 0 to 60 min. But in this case it would go to the maximum value of `data['time']`

.

**Here is what I have tried:**

```
import networkx as nx
import matplotlib.pyplot as plt
import osmnx as ox
import pandas as pd
from shapely.wkt import loads as load_wkt
import numpy as np
import matplotlib.cm as cm
ox.config(log_console=True, use_cache=True)
place = {'city': 'Lisbon', 'country': 'Portugal'}
G = ox.graph_from_place(place, network_type='drive')
hospitals = ox.pois_from_place(place, amenities=['hospital'])
hosp_1 = hospitals.iloc[21]['geometry'] # Hospital Santa Maria
coord_1 = (38.74817825481225, -9.160815118526642) # Coordinate Hospital Santa Maria
target_1 = ox.get_nearest_node(G, coord_1)
nodes, edges = ox.graph_to_gdfs(G, nodes=True, edges=True) # Transforms nodes and edges into Geodataframes
travel_speed = 20 # km/h
meters_per_minute = travel_speed * 1000 / 60
nodes['shortest_route_length_to_target'] = 0
route_lengths = []
i = 0
# print(G.edges(data=True))
for u, v, k, data in G.edges(data=True, keys=True):
data['time'] = data['length'] / meters_per_minute
for node in G.nodes:
try:
route_length = nx.shortest_path_length(G, node, target_1, weight='time')
route_lengths.append(route_length)
nodes['shortest_route_length_to_target'][node] = route_length
except nx.exception.NetworkXNoPath:
continue
def get_colors(n, cmap='viridis', start=0., stop=1., alpha=1.):
colors = [cm.get_cmap(cmap)(x) for x in np.linspace(start, stop, n)]
colors = [(r, g, b, alpha) for r, g, b, _ in colors]
return colors
def get_node_colors_by_attr(G, attr, num_bins=None, cmap='viridis', start=0, stop=1, na_color='none'):
if num_bins is None:
num_bins = len(G.nodes())
bin_labels = range(num_bins)
# attr_values = pd.Series([data[attr] for node, data in G.nodes(data=True)])
attr_values = pd.Series(nodes[attr].values) # Cretaes a dataframe ith the attribute of each node
# print(attr_values)
cats = pd.qcut(x=attr_values, q=num_bins, labels=bin_labels) # Puts the values in bins
# print(cats)
colors = get_colors(num_bins, cmap, start, stop) #List of colors of each bin
node_colors = [colors[int(cat)] if pd.notnull(cat) else na_color for cat in cats]
return node_colors
nc = get_node_colors_by_attr(G, attr='shortest_route_length_to_target', num_bins=10)
ns = [80 if node == target_1 else 20 for node in G.nodes()]
k = 0
for node in G.nodes():
if node == target_1:
nc[k] = str('red')
k += 1
else:
k += 1
G = ox.project_graph(G)
cmap = plt.cm.get_cmap('viridis')
norm=plt.Normalize(vmin=0, vmax=1)
sm = mpl.cm.ScalarMappable(norm=norm, cmap=cmap)
sm.set_array([])
fig, ax = ox.plot_graph(G, node_color=nc, node_size=ns, edge_linewidth=0.5, fig_height = 13, fig_width =13, bgcolor = 'white')
plt.colorbar(sm)
```

**The graph I obtain is the following:**