# Algorithms for optimal student seating arrangements

Say I need to place n=30 students into groups of between 2 and 6, and I collect the following preference data from each student:

Student Name: Tom

Likes to sit with: Jimi, Eric

Doesn't like to sit with: John, Paul, Ringo, George

It's implied that they're neutral about any other student in the overall class that they haven't mentioned.

How might I best run a large number of simulations of many different/random grouping arrangements, to be able to determine a score for each arrangement, through which I could then pick the "most optimal" score/arrangement?

Alternatively, are there any other methods by which I might be able to calculate a solution that satisfies all of the supplied constraints?

I'd like a generic method that can be reused on different class sizes each year, but within each simulation run, the following constants and variables apply:

Constants: Total number of students, Student preferences

Variables: Group sizes, Student Groupings, Number of different group arrangements/iterations to test

• If this is more about feasibility (more or less a high chance that there is a valid solution treating those constraints hard), a SAT-solver will be very hard to beat (giving a good formulation including symmetry-breaking). If chances are slim and this is about min-violation, things might slowly shift towards other techniques like integer-programming (potentially quadratic) or (meta-)heuristics. Monte-carlo like simulation like described is a good basic algorithm, but it should also include local-search and potentially large neighborhood search. And as mentioned: i expect it to be NP-hard too. – sascha Jan 5 at 12:25
• Monte-carlo is trivially implemented and can be used for many variants of this problem. But it will not compete with more advanced / more exploiting approaches. If it's enough for you, use it. So probably also start with it: from simple to more complex. E.g. monte-carlo + local-search as polishing ~ multi-start search(+ a few iterations of lns; but that's usually harder to implement, often using some black-box solver like SAT or CP) You can also start looking into the keyword wedding seating problem. There are different variants and lots of structure is shared. – sascha Jan 5 at 12:33
• No one asked so far about the topology of the class room. If there are multiple rows, solutions might differ (if in front and behind and diagonally in front and behind do not count into the restrictions). I have the feeling topology matters. Maybe even to the class of the problem. – BitTickler Jan 5 at 12:40
• I muse, the problem might actually become algorithmically easier if you do consider topology. A Kohonen network comes to mind as a fancy way to sort it out. Likers attract each other, dislikers repulse each other... on a 2D plane... then snap to grid. – BitTickler Jan 5 at 12:50
• Some real-world raw data as an example can be found here (matrix in xlsx form): dropbox.com/s/nz9qj0z0fyve290/class1_rawData.xlsx?dl=0 – FrugalTPH Jan 5 at 19:45

I believe you can state this as an explicit mathematical optimization problem.

Define the binary decision variables:

``````x(p,g) = 1 if person p is assigned to group g
0 otherwise
``````

I used:

I used your data set with 28 persons, and your preference matrix (with -1,+1,0 elements). For groups, I used 4 groups of 6 and 1 group of 4. A solution can look like:

``````----     80 PARAMETER solution  using MIQP model

group1      group2      group3      group4      group5

aimee               1
amber-la                                                1
amber-le                                                            1
andrina             1
catelyn-t                                   1
charlie                                                 1
charlotte                                   1
cory                            1
daniel                          1
ellie               1
ellis               1
eve                                         1
grace-c                                                 1
grace-g                                                 1
holly                                                   1
jack                            1
james                           1
kieran                                                              1
kristiana                                   1
lily                                                                1
luke                            1
naz                 1
nibah                                       1
niko                            1
wiki                1
zeina                                                   1
COUNT               6           6           6           6           4
``````

Notes:

• This model can be linearized, so it can be fed into a standard MIP solver
• I solved this directly as a MIQP model (actually the solver reformulated the model into a MIP). The model solved in a few seconds.
• Probably we need to add extra logic to make sure one person is not getting a really bad assignment. We optimize here only the total sum. This overall sum may allow an individual to get a bad deal. It is an interesting exercise to take this into account in the model. There are some interesting trade-offs.
• Thanks for this, I'll have a play with the method and see what tuning / tweaks it might need to overcome some of the downfalls you mentioned. – FrugalTPH Jan 13 at 10:55

1st approach should be, create matrix n x n where n is total number of students, indexes for row and columns are ordinals for every student, and each column representing preferences for sitting with the others students. Fills the cells with values 1=Like to sit, -1 = the Opposite, 0 = neutral. Zeroes to be filled too on main diagonal (i,i)

------Mark Maria John Peter

Mark 0 1 -1 1

Maria 0 0 -1 1

John -1 1 0 1

Peter 0

Score calculations are based on sums of these values. So ie: John likes to sit with Maria, = 1, but Maria doesn't like to sit with John -1, result is 0. Best result is when both score (sum) 2.

So on, based on Group Sizes, calculate Score of each posible combination. Bigger the score, better the arrangement. Combinations discriminate values on main diagonal. ie: John grouped with the same John is not a valid combination/group.

In a group size of 2, best score is 2

In a group size of 3, best score is 6,

In a group size of 4, best score is 12

In a group size of n, best score would be (n-1)*n

Now in ordered list of combinations / groups, you should take first the best tuples with highest scores, but avoiding duplicates of students between tuples.

• Thanks for the suggestion, I'll have a play with this amongst other options later when I'm in front of the input date. Thanks again. – FrugalTPH Jan 5 at 14:01

In a recent research, a PSO was implemented to classify students under unknown number of groups of 4 to 6. PSO showed improved capabilities compared to GA. I think that all you need is the specific research.

The paper is: Forming automatic groups of learners using particle swarm optimization for applications of differentiated instruction

You can find the paper here: https://doi.org/10.1002/cae.22191

Perhaps the researchers could guide you through researchgate: https://www.researchgate.net/publication/338078753

Regarding the optimal sitting you need to specify an objective function with the specific data

• Thanks for your input :) – FrugalTPH Jan 13 at 10:54
• you are welcome! I hope i have helped you – Gus Rdrm Jan 13 at 14:57