I'm newbie to algorithm and optimization.

I'm trying to implement **capacitated k-means**, but getting unresolved and poor result so far.

This is used as part of a CVRP simulation (capacitated vehicle routing problem).

I'm curious if I interprets the referenced algorithm wrong.

Ref: "Improved K-Means Algorithm for Capacitated Clustering Problem" (Geetha, Poonthalir, Vanathi)

The simulated CVRP has 15 customers, with 1 depot.

Each customer has Euclidean coordinate (x,y) and demand.

There are 3 vehicles, each has capacity of 90.

So, the capacitated k-means is trying to cluster 15 customers into 3 vehicles, with the total demands in each cluster must not exceed vehicle capacity.

**UPDATE:**

In the referenced algorithm, I couldn't catch any information about what must the code do when it runs out of "next nearest centroid".

That is, when all of the "nearest centroids" has been examined, in the **step 14.b** below, while the `customers[1]`

is still unassigned.

This results in the customer with index 1 being unassigned.

Note: `customer[1]`

is customer with largest demand (30).

**Q: When this condition is met, what the code should do then?**

Here is my interpretation of the referenced algorithm, please correct my code, thank you.

- Given
`n`

requesters (customers),`n`

=`customerCount`

, and a depot - n demands,
n coordinates (x,y)

calculate number of clusters,

`k`

= (sum of all demands) /`vehicleCapacity`

select initial centroids,

5.a. sort customers based on`demand`

, in descending order =`d_customers`

,

5.b. select`k`

first customers from`d_customers`

as initial centroids =`centroids[0 .. k-1]`

,Create binary matrix

`bin_matrix`

, dimension =`(customerCount) x (k)`

,

6.a. Fill`bin_matrix`

with all zerosstart WHILE loop, condition = WHILE

`not converged`

.

7.a.`converged = False`

start FOR loop, condition = FOR

`each customers`

,

8.a. index of customer = icalculate Euclidean distances from

`customers[i]`

to all`centroids`

=>`edist`

9.a. sort`edist`

in ascending order,

9.b. select first`centroid`

with closest distance =`closest_centroid`

start WHILE loop, condition =

`while customers[i]`

is not assigned to any cluster.group all the other unassigned customers =

`G`

,

11.a. consider`closest_centroid`

as centroid for`G`

.calculate priorities

`Pi`

for each`customers`

of`G`

,

12.a. Priority`Pi = (distance from customers[i] to closest_cent) / demand[i]`

12.b. select a customer with highest priority`Pi`

.

12.c. customer with highest priority has index =`hpc`

**12.d. Q: IF highest priority customer cannot be found, what must we do ?**assign

`customers[hpc]`

to`centroids[closest_centroid]`

if possible.

13.a. demand of`customers[hpc]`

=`d1`

,

13.b. sum of all demands of centroids' members =`dtot`

,

13.c.`IF (d1 + dtot) <= vehicleCapacity, THEN`

..

13.d. assign`customers[hpc]`

to`centroids[closest_centroid]`

13.e. update`bin_matrix`

, row index =`hpc`

, column index =`closest_centroid`

, set to`1`

.IF

`customers[i]`

is (still)`not assigned`

to any cluster, THEN..

14.a. choose the`next nearest centroid`

, with the next nearest distance from`edist`

.

**14.b. Q: IF there is no next nearest centroid, THEN what must we do ?**calculate converged by comparing previous matrix and updated matrix bin_matrix.

15.a. IF no changes in the`bin_matrix`

, then set`converged = True`

.otherwise, calculate

`new centroids`

from updated clusters.

16.a. calculate new`centroids' coordinates`

based on members of each cluster.

16.b.`sum_x`

= sum of all`x-coordinate`

of a cluster`members`

,

16.c.`num_c`

= number of all`customers (members)`

in the cluster,

16.d. new centroid's`x-coordinate`

of the cluster =`sum_x / num_c`

.

16.e. with the same formula, calculate new centroid's`y-coordinate`

of the cluster =`sum_y / num_c`

.iterate the main WHILE loop.

My code is always ended with unassigned customer at the **step 14.b**.

That is when there is a `customers[i]`

still not assigned to any centroid, and it has run out of "next nearest centroid".

And the resulting clusters is poor. Output graph:

-In the picture, star is centroid, square is depot.

In the pic, customer labeled "1", with demand=30 always ended with no assigned cluster.

Output of the program,

```
k_cluster 3
idx [ 1 -1 1 0 2 0 1 1 2 2 2 0 0 2 0]
centroids [(22.6, 29.2), (34.25, 60.25), (39.4, 33.4)]
members [[3, 14, 12, 5, 11], [0, 2, 6, 7], [9, 8, 4, 13, 10]]
demands [86, 65, 77]
```

First and third cluster is poorly calculated.

`idx`

with index '`1`

' is not assigned (`-1`

)

**Q: What's wrong with my interpretation and my implementation?**

Any correction, suggestion, help, will be very much appreciated, thank you in advanced.

Here is my full code:

```
#!/usr/bin/python
# -*- coding: utf-8 -*-
# pastebin.com/UwqUrHhh
# output graph: i.imgur.com/u3v2OFt.png
import math
import random
from operator import itemgetter
from copy import deepcopy
import numpy
import pylab
# depot and customers, [index, x, y, demand]
depot = [0, 30.0, 40.0, 0]
customers = [[1, 37.0, 52.0, 7], \
[2, 49.0, 49.0, 30], [3, 52.0, 64.0, 16], \
[4, 20.0, 26.0, 9], [5, 40.0, 30.0, 21], \
[6, 21.0, 47.0, 15], [7, 17.0, 63.0, 19], \
[8, 31.0, 62.0, 23], [9, 52.0, 33.0, 11], \
[10, 51.0, 21.0, 5], [11, 42.0, 41.0, 19], \
[12, 31.0, 32.0, 29], [13, 5.0, 25.0, 23], \
[14, 12.0, 42.0, 21], [15, 36.0, 16.0, 10]]
customerCount = 15
vehicleCount = 3
vehicleCapacity = 90
assigned = [-1] * customerCount
# number of clusters
k_cluster = 0
# binary matrix
bin_matrix = []
# coordinate of centroids
centroids = []
# total demand for each cluster, must be <= capacity
tot_demand = []
# members of each cluster
members = []
# coordinate of members of each cluster
xy_members = []
def distance(p1, p2):
return math.sqrt((p1[0] - p2[0])**2 + (p1[1] - p2[1])**2)
# capacitated k-means clustering
# http://www.dcc.ufla.br/infocomp/artigos/v8.4/art07.pdf
def cap_k_means():
global k_cluster, bin_matrix, centroids, tot_demand
global members, xy_members, prev_members
# calculate number of clusters
tot_demand = sum([c[3] for c in customers])
k_cluster = int(math.ceil(float(tot_demand) / vehicleCapacity))
print 'k_cluster', k_cluster
# initial centroids = first sorted-customers based on demand
d_customers = sorted(customers, key=itemgetter(3), reverse=True)
centroids, tot_demand, members, xy_members = [], [], [], []
for i in range(k_cluster):
centroids.append(d_customers[i][1:3]) # [x,y]
# initial total demand and members for each cluster
tot_demand.append(0)
members.append([])
xy_members.append([])
# binary matrix, dimension = customerCount-1 x k_cluster
bin_matrix = [[0] * k_cluster for i in range(len(customers))]
converged = False
while not converged: # until no changes in formed-clusters
prev_matrix = deepcopy(bin_matrix)
for i in range(len(customers)):
edist = [] # list of distance to clusters
if assigned[i] == -1: # if not assigned yet
# Calculate the Euclidean distance to each of k-clusters
for k in range(k_cluster):
p1 = (customers[i][1], customers[i][2]) # x,y
p2 = (centroids[k][0], centroids[k][1])
edist.append((distance(p1, p2), k))
# sort, based on closest distance
edist = sorted(edist, key=itemgetter(0))
closest_centroid = 0 # first index of edist
# loop while customer[i] is not assigned
while assigned[i] == -1:
# calculate all unsigned customers (G)'s priority
max_prior = (0, -1) # value, index
for n in range(len(customers)):
pc = customers[n]
if assigned[n] == -1: # if unassigned
# get index of current centroid
c = edist[closest_centroid][1]
cen = centroids[c] # x,y
# distance_cost / demand
p = distance((pc[1], pc[2]), cen) / pc[3]
# find highest priority
if p > max_prior[0]:
max_prior = (p, n) # priority,customer-index
# if highest-priority is not found, what should we do ???
if max_prior[1] == -1:
break
# try to assign current cluster to highest-priority customer
hpc = max_prior[1] # index of highest-priority customer
c = edist[closest_centroid][1] # index of current cluster
# constraint, total demand in a cluster <= capacity
if tot_demand[c] + customers[hpc][3] <= vehicleCapacity:
# assign new member of cluster
members[c].append(hpc) # add index of customer
xy = (customers[hpc][1], customers[hpc][2]) # x,y
xy_members[c].append(xy)
tot_demand[c] += customers[hpc][3]
assigned[hpc] = c # update cluster to assigned-customer
# update binary matrix
bin_matrix[hpc][c] = 1
# if customer is not assigned then,
if assigned[i] == -1:
if closest_centroid < len(edist)-1:
# choose the next nearest centroid
closest_centroid += 1
# if run out of closest centroid, what must we do ???
else:
break # exit without centroid ???
# end while
# end for
# Calculate the new centroid from the formed clusters
for j in range(k_cluster):
xj = sum([cn[0] for cn in xy_members[j]])
yj = sum([cn[1] for cn in xy_members[j]])
xj = float(xj) / len(xy_members[j])
yj = float(yj) / len(xy_members[j])
centroids[j] = (xj, yj)
# calculate converged
converged = numpy.array_equal(numpy.array(prev_matrix), numpy.array(bin_matrix))
# end while
def clustering():
cap_k_means()
# debug plot
idx = numpy.array([c for c in assigned])
xy = numpy.array([(c[1], c[2]) for c in customers])
COLORS = ["Blue", "DarkSeaGreen", "DarkTurquoise",
"IndianRed", "MediumVioletRed", "Orange", "Purple"]
for i in range(min(idx), max(idx)+1):
clr = random.choice(COLORS)
pylab.plot(xy[idx==i, 0], xy[idx==i, 1], color=clr, \
linestyle='dashed', \
marker='o', markerfacecolor=clr, markersize=8)
pylab.plot(centroids[:][0], centroids[:][1], '*k', markersize=12)
pylab.plot(depot[1], depot[2], 'sk', markersize=12)
for i in range(len(idx)):
pylab.annotate(str(i), xy[i])
pylab.savefig('clust1.png')
pylab.show()
return idx
def main():
idx = clustering()
print 'idx', idx
print 'centroids', centroids
print 'members', members
print 'demands', tot_demand
if __name__ == '__main__':
main()
```