I have groups of volunteers of various sizes (from 5 people to 250 people) that need to be paired with volunteer sites requesting various numbers of volunteers (from 3 people to 400 people). I need to pair volunteer groups with volunteer sites, splitting volunteer groups when needed and pairing multiple volunteer groups with a single volunteer site when necessary. However, I would like to minimize any splitting. Is there an algorithm to pair these most optimally? Does this fall under a known type of computer science problem that has Wikipedia pages which would help? Any suggestions are appreciated!

What you describe sounds a bit like a flow network but the minimizing of splits does not really fit in. I think although the algorithms about weighted max/min bipartite matching might give you some ideas on how to develop an algorithm for your problem. I'd personally try to model the problem using constraint programming. – Bakuriu Jan 25 at 19:47
This problem can be interpreted as a variant of the transportation problem. Consider the bipartite graph with source nodes (volunteer groups, denoted by i
) and destination nodes (volunteer sites, denoted by j
). Let's assume the total number of volunteers is equal or larger than total demand by the sites. Then the objective is to minimize the number of used links from i → j
.
This problem can be formulated as a mixed integer programming model and solved with readily available MIP solvers. The model can look like:
The items x^{up}_{i,j} indicate the upperbounds on x_{i,j}.
Let's generate some random data:
 18 PARAMETER size volunteers in group
group1 47, group2 212, group3 140, group4 79, group5 76, group6 60, group7 91
group8 215, group9 21, group10 128, group11 250, group12 147
 18 PARAMETER request needed by site
site1 397, site2 306, site3 55, site4 257, site5 66
 18 PARAMETER numvolunteer = 1466 total volunteers
PARAMETER numrequest = 1081 total requests
When feeding this data into our model we get the following results:
 44 VARIABLE y.L link used
site1 site2 site3 site4 site5
group2 1
group3 1
group4 1
group5 1
group8 1
group10 1
group11 1
group12 1
 44 VARIABLE x.L flow
site1 site2 site3 site4 site5
group2 91
group3 140
group4 66
group5 55
group8 215
group10 117
group11 250
group12 147
I will need more specifics on what you are trying to optimize, but here is a solution that will get it done.
Things you may want to consider:
 Do you want to allocate the maximum number of people possible or the maximum number of groups? My algorithm is made to maximize the number of matched groups.
 Do you still want to match incomplete groups? My algorithm might create 1 volunteer match that is incomplete, but I thought that it might be worthwhile anyway, and then you can just fill it later.
First, create two dictionaries, volunteerGroups (with a key for the group number or name, and the number needed as the value) and a volunteersNeeded (with a key for the group number or name and the number needed as the value). Use collections to sort the dictionaries.
import collections
volunteerGroups = collections.OrderedDict(sorted(volunteerGroups.items()))
volunteersNeeded = collections.OrderedDict(sorted(volunteersNeeded.items()))
Create a dictionary for the matchings:
volunteerMatches = {}
Next, start by finding a fit for the smallest amounts of volunteers needed.
for v in volunteersNeeded.keys():
matches = False
for v2 in volunteerGroup.keys():
if volunteerGroup[v2]>=volunteersNeeded[v]:
volunteerMatches[v] = v2 #dictionary entry matching group to assignment
#remove matched groups
del volunteerGroup[v2]
del volunteerGroup[v]
#Now match any groups that couldn't fit 1 to 1
for v in volunteersNeeded.keys():
matched = false
vg = volunteerGroups.keys()
volunteerMatches[v] = []
while matched == false and len(vg)>0:
for v2 in volunteerGroups.keys():
if volunteersNeeded[v]>0:
volunteersNeeded[v] = volunteersNeeded[v]volunteerGroups[v2]
volunteerMatches[v].append(volunteerGroups[v2])
del volunteerGroups[v2] #delete the group that was added to this project
#once you finish a group, you can move on
if volunteersNeeded[v]<=0:
matched = true
break
#print out all the matches
for match in volunteerMatches.keys():
print(volunteerMatches[match])