How do I solve a Travelling Salesman problem in python? I did not find any library, there should be a way using scipy functions for optimization or other libraries.
My hacky-extremelly-lazy-pythonic bruteforcing solution is:
tsp_solution = min( (sum( Dist[i] for i in izip(per, per[1:])), n, per) for n, per in enumerate(i for i in permutations(xrange(Dist.shape[0]), Dist.shape[0])) )[2]
where Dist (numpy.array) is the distance matrix. If Dist is too big this will take forever.
Suggestions?
The scipy.optimize functions are not constructed to allow straightforward adaptation to the traveling salesman problem (TSP). For a simple solution, I recommend the 2-opt algorithm, which is a well-accepted algorithm for solving the TSP and relatively straightforward to implement. Here is my implementation of the algorithm:
import numpy as np
# Calculate the euclidian distance in n-space of the route r traversing cities c, ending at the path start.
path_distance = lambda r,c: np.sum([np.linalg.norm(c[r[p]]-c[r[p-1]]) for p in range(len(r))])
# Reverse the order of all elements from element i to element k in array r.
two_opt_swap = lambda r,i,k: np.concatenate((r[0:i],r[k:-len(r)+i-1:-1],r[k+1:len(r)]))
def two_opt(cities,improvement_threshold): # 2-opt Algorithm adapted from https://en.wikipedia.org/wiki/2-opt
route = np.arange(cities.shape[0]) # Make an array of row numbers corresponding to cities.
improvement_factor = 1 # Initialize the improvement factor.
best_distance = path_distance(route,cities) # Calculate the distance of the initial path.
while improvement_factor > improvement_threshold: # If the route is still improving, keep going!
distance_to_beat = best_distance # Record the distance at the beginning of the loop.
for swap_first in range(1,len(route)-2): # From each city except the first and last,
for swap_last in range(swap_first+1,len(route)): # to each of the cities following,
new_route = two_opt_swap(route,swap_first,swap_last) # try reversing the order of these cities
new_distance = path_distance(new_route,cities) # and check the total distance with this modification.
if new_distance < best_distance: # If the path distance is an improvement,
route = new_route # make this the accepted best route
best_distance = new_distance # and update the distance corresponding to this route.
improvement_factor = 1 - best_distance/distance_to_beat # Calculate how much the route has improved.
return route # When the route is no longer improving substantially, stop searching and return the route.
Here is an example of the function being used:
# Create a matrix of cities, with each row being a location in 2-space (function works in n-dimensions).
cities = np.random.RandomState(42).rand(70,2)
# Find a good route with 2-opt ("route" gives the order in which to travel to each city by row number.)
route = two_opt(cities,0.001)
And here is the approximated solution path shown on a plot:
import matplotlib.pyplot as plt
# Reorder the cities matrix by route order in a new matrix for plotting.
new_cities_order = np.concatenate((np.array([cities[route[i]] for i in range(len(route))]),np.array([cities[0]])))
# Plot the cities.
plt.scatter(cities[:,0],cities[:,1])
# Plot the path.
plt.plot(new_cities_order[:,0],new_cities_order[:,1])
plt.show()
# Print the route as row numbers and the total distance travelled by the path.
print("Route: " + str(route) + "\n\nDistance: " + str(path_distance(route,cities)))
If the speed of algorithm is important to you, I recommend pre-calculating the distances and storing them in a matrix. This dramatically decreases the convergence time.
Edit: Custom Start and End Points
For a non-circular path (one which ends at a location different from where it starts), edit the path distance formula to
path_distance = lambda r,c: np.sum([np.linalg.norm(c[r[p+1]]-c[r[p]]) for p in range(len(r)-1)])
and then reorder the cities for plotting using
new_cities_order = np.array([cities[route[i]] for i in range(len(route))])
With the code as it is, the starting city is fixed as the first city in cities, and the ending city is variable.
To make the ending city the last city in cities, restrict the range of swappable cities by changing the range of swap_first and swap_last in two_opt() with the code
for swap_first in range(1,len(route)-3):
for swap_last in range(swap_first+1,len(route)-1):
To make both the starting and ending cities variable, instead expand the range of swap_first and swap_last with
for swap_first in range(0,len(route)-2):
for swap_last in range(swap_first+1,len(route)):
path_distance for non-circular paths. With a non-circular path, you may also want to customize the start and end points, so I've added a note on how to customize those as well. Note that I've made a slight modification to two_opt_swap to accommodate a variable starting city.
May 20, 2017 at 16:13
path_distance function, but I don't really know if 2-opt works for asymmetrical cases :?
I recently found out this option to use linear optimization for the TSP problem
https://gist.github.com/mirrornerror/a684b4d439edbd7117db66a56f2483e0
Nonetheless I agree with some of the other comments, just a remainder that there are ways to use linear optimization for this problem.
Some academic publications include the following http://www.opl.ufc.br/post/tsp/ https://phabi.ch/2021/09/19/tsp-subtour-elimination-by-miller-tucker-zemlin-constraint/
there's 'graph' lib in Python exactly for Network Problems (vertex cover optimization problem in theoretical computer science & operations research) - NetworkX. In its docs (Reference/Algorithms/Approximations and Heuristics) you can find an example (perhaps, it could be more convinient than scipy for such problem type - incl. shortest path problem, min cost flow problem , etc). TSP:
The NP-hard graphical traveling salesman problem (GTSP) is to find a closed walk of total minimum weight that visits each vertex in an undirected edge-weighted and not necessarily complete graph.
"""
==========================
Traveling Salesman Problem
==========================
This is an example of a drawing solution of the traveling salesman problem
The function used to produce the solution is `christofides <networkx.algorithms.approximation.traveling_salesman.christofides>`,
where given a set of nodes, it calculates the route of the nodes
that the traveler has to follow in order to minimize the total cost.
"""
import matplotlib.pyplot as plt
import networkx as nx
import networkx.algorithms.approximation as nx_app
import math
G = nx.random_geometric_graph(20, radius=0.4, seed=3)
pos = nx.get_node_attributes(G, "pos")
# Depot should be at (0,0)
pos[0] = (0.5, 0.5)
H = G.copy()
# Calculating the distances between the nodes as edge's weight.
for i in range(len(pos)):
for j in range(i + 1, len(pos)):
dist = math.hypot(pos[i][0] - pos[j][0], pos[i][1] - pos[j][1])
dist = dist
G.add_edge(i, j, weight=dist)
cycle = nx_app.christofides(G, weight="weight")
edge_list = list(nx.utils.pairwise(cycle))
# Draw closest edges on each node only
nx.draw_networkx_edges(H, pos, edge_color="blue", width=0.5)
# Draw the route
nx.draw_networkx(
G,
pos,
with_labels=True,
edgelist=edge_list,
node_color = 'r',
edge_color="red",
node_size=200,
width=3,
)
print("The route of the traveller is:", cycle)
plt.show()
Note: there's different Algorithms for your problem in networkX's docs
Formulation: Branch-And-Cut Algorithms For The Covering Salesman Problem
