More queens problems (2)

In [1], I discussed the Minimum Dominating Set of Queens Problem. Here is a variant:

Given an \(n \times n\) chess board, place \(n\) queens on the board such that the number of squares not under attack is maximized. 

For an \(n=8\) problem, the maximum number of non-dominated squares is 11. An example is:

11 white pawns are not under attack

We base the model on the one in [1]. First we define two sets of binary variables:

\[\begin{align} & x_{i,j} = \begin{cases} 1 & \text{if square \((i,j)\) is occupied by a queen}\\ 0 & \text{otherwise}\end{cases} \\ & y_{i,j} = \begin{cases} 1 & \text{if square \((i,j)\) is under attack} \\ 0 & \text{otherwise}\end{cases}\end{align}\]

The model can look like:

Maximum Non-Dominated Squares Problem

\[\begin{align}\max& \>\color{DarkRed}z=\sum_{i,j} \left(1-\color{DarkRed} y_{i,j}\right)\\ & \sum_{j'} \color{DarkRed}x_{i,j'} + \sum_{i'} \color{DarkRed}x_{i',j} + \sum_{i',j'|i'-j'=i-j} \color{DarkRed}x_{i',j'} +\sum_{i',j'|i'+j'=i+j} \color{DarkRed}x_{i',j'}-3 \color{DarkRed} x_{i,j} \ge \color{DarkBlue}M \cdot \color{DarkRed}y_{i,j} && \forall i,j \\  & \sum_{i,j}  \color{DarkRed} x_{i,j} = n \\& \color{DarkRed}x_{i,j},\color{DarkRed}y_{i,j}\in\{0,1\} \end{align}\]

The funny term \(-3x_{i,j}\) is to compensate for double counting occurrences of \(x_{i,j}\) in the previous terms [1]. We need to find a reasonable value for \(M\). An upper bound is \(M=n\). For \(n=8\), there are 48 different optimal solutions.

The problem \(n=9\) has one structural optimal solution (with 18 unattacked positions), and 3 variants by symmetry:

Is there a good way to find only structural solutions? One way is to use your own cuts as in [4], If we want to use the solution pool technology, we need to invent a constraint that forbids some symmetry (or have an objective that favors some of symmetric versions).

References

1. More queens problems, https://yetanothermathprogrammingconsultant.blogspot.com/2018/12/more-queens-problems.html
2. Bernard Lemaire, Pavel Vitushinkiy, Placing \(n\) non-dominating queens on the \(n\times n\) Chessboard, 2011, https://www.ffjm.org/upload/fichiers/N_NON_DOMINATING_QUEENS.pdf
3. Maximum Queens Chess Problem, https://www.gams.com/latest/gamslib_ml/queens.103

More queens problems

In [1] the famous \(n\)-queens problem was discussed: how many queens can we place on a chess-board such that non of them are attacked by others. Interestingly, we had some non-obvious problem with Cplex enumerating the different configurations (due to tolerance issues).

A different problem is the Minimum Dominating Set of Queens Problem:

Find the minimum number of queens needed such that they dominate each square.

Here dominate means: either a square is under attack by at least one queen, or it is occupied by a queen.

To develop a Mixed Integer Programming model, we introduce the familiar binary variables:

\[x_{i,j} = \begin{cases} 1 & \text{if square \((i,j)\) is occupied by a queen}\\ 0 & \text{otherwise}\end{cases}\]

A square \((i,j)\) is dominated if:

1. \(x_{i,j}=1\): a queen is located here. This case will be covered by the following other cases, so we don't have to worry about this.
2. There is a queen in row \(i\): \[\sum_{j'} x_{i,j'} \ge 1\]
3. There is a queen in column \(j\):\[\sum_{i'} x_{i',j} \ge 1\]
4. There is a queen in the same diagonal. The diagonal is described by \((i',j')\) such that \(i'-j'=i-j\). So we have: \[\sum_{i',j'|i'-j'=i-j} x_{i',j'}\ge 1\] If you prefer you can write this as \[\sum_{i'|1 \le i'-i+j \le n } x_{i',i'-i+j} \ge 1 \] 
5. There is a queen in the same anti-diagonal. The anti-diagonal is described by \((i',j')\) such that \(i'+j'=i+j\). So we have: \[\sum_{i',j'|i'+j'=i+j} x_{i',j'}\ge 1\] This can also be written as \[\sum_{i'| 1 \le i+j-i' \le n} x_{i',i+j-i'} \ge 1\]

We can write these conditions in one big constraint. So we can write:

Minimum Dominating Set of Queens Problem
\[\begin{align}\min& \>\color{DarkRed}z=\sum_{i,j} \color{DarkRed} x_{i,j}\\ & \sum_{j'} \color{DarkRed}x_{i,j'} + \sum_{i'} \color{DarkRed}x_{i',j} + \sum_{i',j'|i'-j'=i-j} \color{DarkRed}x_{i',j'} +\sum_{i',j'|i'+j'=i+j} \color{DarkRed}x_{i',j'} \ge 1 && \forall i,j \\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

For an \(8\times 8\) board, we need 5 queens. Here are two solutions:

You can verify that every unoccupied square is under attack.

Note that this formulation actually does a bit of double counting. E.g. when we look at the constraint for cell \((2,3)\) we see:

e(2,3)..  x(1,2) + x(1,3) + x(1,4) + x(2,1) + x(2,2) + 4*x(2,3) + x(2,4)
     
      + x(2,5) + x(2,6) + x(2,7) + x(2,8) + x(3,2) + x(3,3) + x(3,4) + x(4,1)
     
      + x(4,3) + x(4,5) + x(5,3) + x(5,6) + x(6,3) + x(6,7) + x(7,3) + x(7,8)
     
      + x(8,3) =G= 1 ; (LHS = 0, INFES = 1 ****)

We see that x(2,3) has a coefficient 4. This is harmless. However it looks a bit unpolished. With a little bit more careful modeling we can get rid of this coefficient 4. A complicated way would be: \[ \sum_{j'}x_{i,j'} + \sum_{i'|i'\ne i} x_{i',j} + \sum_{i',j'|i'-j'=i-j,i'\ne i, j'\ne j} x_{i',j'} +\sum_{i',j'|i'+j'=i+j,i'\ne i, j'\ne j} x_{i',j'} \ge 1 \>\> \forall i,j\] The first summation includes \(x_{i,j}\) while the other three summations exclude explicitly an occurrence of \(x_{i,j}\). Simpler is just to subtract \(3 x_{i,j}\): \[\sum_{j'} x_{i,j'} + \sum_{i'} x_{i',j} + \sum_{i',j'|i'-j'=i-j} x_{i',j'} +\sum_{i',j'|i'+j'=i+j} x_{i',j'}-3x_{i,j} \ge 1\>\> \forall i,j\] Here we just compensate for the double counting.

Now we see:

e(2,3)..  x(1,2) + x(1,3) + x(1,4) + x(2,1) + x(2,2) + x(2,3) + x(2,4) + x(2,5)
     
      + x(2,6) + x(2,7) + x(2,8) + x(3,2) + x(3,3) + x(3,4) + x(4,1) + x(4,3)
     
      + x(4,5) + x(5,3) + x(5,6) + x(6,3) + x(6,7) + x(7,3) + x(7,8) + x(8,3)

      =G= 1 ; (LHS = 0, INFES = 1 ****)

When we ask: how many different solution are there?, we use again the Cplex solution pool. And again, we have our tolerance problem:

pool.absgap	Number of solutions
0	2
0.5	4860

As the objective is integer valued, in some sense an absolute gap tolerance of 0.5 seems the safest. With this we find the correct number of solutions [2]. See [1] for a more in-depth discussion of this tolerance problem.

References

1. Chess and solution pool, http://yetanothermathprogrammingconsultant.blogspot.com/2018/11/chess-and-solution-pool.html.
2. Weisstein, Eric W.,  Queens Problem, http://mathworld.wolfram.com/QueensProblem.html
3. Henning Fernau, minimum dominating set of queens: A trivial programming exercise?, Discrete Applied Mathematics, Volume 158, Issue 4, 28 February 2010, Pages 308-318. This is about programming instead of modeling. The issues are very different.
4. Saad Alharbi and, Ibrahim Venkat, A Genetic Algorithm Based Approach for Solving the Minimum Dominating Set of Queens Problem, Hindawi Journal of Optimization, Volume 2017. I am not sure why a meta-heuristic is a good choice for solving this problem: you will not find proven optimal solutions. 

Chess and solution pool

The \(n\)-queens problem is a popular example of a "chessboard non-attacking problem" [1,2]:

• On an \(n \times n\) chessboard place as many queens as possible such that none of them is attacked
• Given this, how many different ways can we place those queens?

We use the usual \(8 \times 8\) board.

Rooks

A related, simpler problem is about placing rooks. The optimization problem is very simple: it is an assignment problem:

n-Rooks Problem
\[\begin{align}\max&\> \color{DarkRed}z=\sum_{i,j} \color{DarkRed} x_{i,j}\\ & \sum_j \color{DarkRed}x_{i,j} \le 1 && \forall i\\& \sum_i \color{DarkRed}x_{i,j} \le 1 && \forall j\\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

For an \(8 \times 8\) board it is obvious that the number of rooks we can place is 8. Here we show two configurations:

We can easily answer: how many alternative configuration with 8 rooks can we find? This is \[n! = 8! = 40,320\] Basically, we enumerate all row and column permutations of the diagonal depicted above. We can use the solution pool in solvers like Cplex and Gurobi to find all of them. Here I use Cplex and the performance is phenomenal: all 40,320 solutions are found in 16 seconds.

Board

In the models in this write-up, I assume a board that has the coordinates:

Coordinate System in Models

This also means that the diagonals:

Main diagonal and anti-diagonal

have the form \(\{(i,j)|i=j\}\) and \(\{(i,j)|i+j=9\}\). More generally, for the downward sloping main diagonals we have the rule: \[i=j+k\] for \(k=-6,\dots,6\). The anti-diagonals can be described as: \[i+j=k\] for \(k=3,\dots,15\). We can illustrate this with:

Diagonals and anti-diagonals

The first picture has cell values \(a_{i,j}=i-j\) and the second one has cell values \(a_{i,j}=i+j\).

Bishops

The model for placing bishops is slightly more complicated: we need to check the main diagonals and the anti-diagonals. We use the notation from the previous paragraph. So with this, our model can look like:

n-Bishops Problem
\[\begin{align}\max& \>\color{DarkRed}z=\sum_{i,j} \color{DarkRed} x_{i,j}\\ & \sum_{i-j=k} \color{DarkRed}x_{i,j} \le 1 && k=-(n-2),\dots,(n-2)\\& \sum_{i+j=k} \color{DarkRed}x_{i,j} \le 1 && k=3,\dots,2n-1\\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

Note that these constraints translate directly into GAMS:

bishop_main(k1).. sum((i,j)$(v(i)-v(j)=v(k1)),x(i,j)) =l= 1;
bishop_anti(k2).. sum((i,j)$(v(i)+v(j)=v(k2)),x(i,j)) =l= 1;

Two possible solutions are:

We can accommodate 14 bishops. There are 256 different solutions (according to Cplex).

Note: the GAMS display of the solution is not so useful:

----     47 VARIABLE x.L  

            1           2           4           5           7           8

1           1                       1           1           1
2           1
3           1                                                           1
6           1                                                           1
7                                                                       1
8           1           1           1           1

For this reason I show the solution using the \(\LaTeX\) chessboard package [5]. You should be aware that the coordinate system is different than what we use in the models.

Queens

The \(n\) queens problem is now very simple: we just need to combine the two previous models.

n-Queens Problem
\[\begin{align}\max&\> \color{DarkRed}z= \sum_{i,j} \color{DarkRed} x_{i,j}\\ & \sum_j \color{DarkRed}x_{i,j} \le 1 && \forall i\\& \sum_i \color{DarkRed}x_{i,j} \le 1 && \forall j\\ & \sum_{i-j=k} \color{DarkRed}x_{i,j} \le 1 && k=-(n-2),\dots,(n-2)\\& \sum_{i+j=k} \color{DarkRed}x_{i,j} \le 1 && k=3,\dots,2n-1\\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

A solution can look like:

We can place 8 queens and there are 92 solutions.

Notes:

• Cplex delivered 91 solutions. This seems to be a tolerance issue. I used a solution pool absolute gap of zero (option SolnPoolAGap=0 or as it is called recently: mip.pool.absgap=0) [4]. As the objective jumps by one, it is safe to set the absolute gap to 0.01. With this gap we found all 92 solutions. Is this a bug? Maybe. Possibly. Probably. This 92-th solution is not supposed to be cut off. Obviously, poor scaling is not an issue here: this model is as well-scaled as you can get. I suspect that the (somewhat poorly understood) combination of tolerances (feasibility, integer, optimality) causes Cplex to behave this way. If too many binary variables assume 0.99999 (say within the integer tolerance) we have an objective which is too small. Indeed, we can also get to 92 solutions by setting the integer tolerance epint=0.  Note that setting the integer tolerance to zero will often increase solution times.
  Often tolerances "help" us: they make it easier to find feasible or optimal solutions. Here is a case when they really cause problems.
  Of course this discussion is not a good advertisement for Mixed Integer Programming models. Preferably we should not have to worry about technical details such as tolerances when building and solving models that are otherwise fairly straightforward (no big-M's, well-scaled, small in size).
• A two step algorithm can help to prevent the tolerance issue discussed above:
  
  1. Solve the maximization problem: we find max number of queens \(z^*\).
  2. Create a feasibility problem with number of queens equal to \(z^*\). I.e. we add the constraint: \[\sum_{i,j} x_{i,j}=z^*\] This problem has no objective. Find all feasible integer solutions using the solution pool. We don't need to set a solution pool gap for this.
  On the surface, this looks just like the method above. However, physically having the constraint \(\sum x_{i,j}=z^*\) in the model will make sure all relaxations obey this constraints. So any binary variables that are automatically integer (i.e. close to 0 or 1) will never cause us to deviate too much from \(z^*\). This is subtle.
• Many of the 92 solutions are the result of simple symmetric operations, such as rotating the board, or reflection [2]. The number of different solutions after ignoring these symmetries is just 12. The GAMS model in [3] finds those.
• The model in [3] handles the bishop constraints differently, by calculating an offset and writing \[\sum_i x_{i,i +\mathit{sh}_s} \le 1 \>\>\forall s\] I somewhat prefer our approach.  

Kings

Kings are handled quite cleverly in [1]. They observe that there cannot be more than one king in each block \[\begin{matrix} x_{i,j} & x_{i,j+1}\\ x_{i+1,j} & x_{i+1,j+1}\end{matrix}\] Note that we only have to look forward (and downward) as a previous block would have covered things to the left (or above). The model can look like:

n-Kings Problem
\[\begin{align}\max& \>\color{DarkRed}z=\sum_{i,j} \color{DarkRed} x_{i,j}\\ & \color{DarkRed}x_{i,j}+\color{DarkRed}x_{i+1,j}+\color{DarkRed}x_{i,j+1}+\color{DarkRed}x_{i+1,j+1}\le 1 && \forall i,j\le n-1\\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

Two solutions are:

We can place 16 kings, and there are a lot of possible configurations: 281,571 (says Cplex).

Knights

To place knights we set up a set \(\mathit{jump}_{i,j,i',j'}\) indicating if we can jump from cell \((i,j)\) to cell \((i',j')\). We only need to look forward, so for each \((i,j)\) we need to consider four cases:

	\(j\)	\(j+1\)	\(j+2\)
\(i-2\)		\(x_{i-2,j+1}\)
\(i-1\)			\(x_{i-1,j+2}\)
\(i\)	\(x_{i,j}\)
\(i+1\)			\(x_{i+1,j+2}\)
\(i+2\)		\(x_{i+2,j+1}\)

Note that near the border we may have fewer than four cases. In GAMS we can populate the set \(\mathit{jump}\) straightforwardly:

jump(i,j,i-2,j+1) = yes;
jump(i,j,i-1,j+2) = yes;
jump(i,j,i+1,j+2) = yes;
jump(i,j,i+2,j+1) = yes;

The model can look like:

n-Knights Problem
\[\begin{align}\max& \>\color{DarkRed}z=\sum_{i,j} \color{DarkRed} x_{i,j}\\ & \color{DarkRed}x_{i,j}+\color{DarkRed}x_{i',j'}\le 1 && \forall i,j,i',j'|\mathit{jump}_{i,j,i',j'}\\ & \color{DarkRed}x_{i,j}\in\{0,1\} \end{align}\]

We can place 32 knights. There are only two different solutions:

Conclusion

The solution pool is a powerful tool to enumerate possibly large numbers of integer solutions. However, with default tolerances, setting the solution pool absolute gap tolerance to zero may cause perfectly good integer solutions to be missed. This is dicey stuff.

References

1. L. R. Foulds and D. G. Johnston, An Application of Graph Theory and Integer Programming: Chessboard Non-Attacking Puzzles, Mathematics Magazine Vol. 57, No. 2 (Mar., 1984), pp. 95-104
2. Eight queens puzzle, https://en.wikipedia.org/wiki/Eight_queens_puzzle
3. Maximum Queens Chess Problem, https://www.gams.com/latest/gamslib_ml/queens.103
4. Absolute gap for solution pool, https://www.ibm.com/support/knowledgecenter/en/SSSA5P_12.7.0/ilog.odms.cplex.help/CPLEX/Parameters/topics/SolnPoolAGap.html
5. chessboard – Print chess boards, https://ctan.org/pkg/chessboard
6. Danna E., Fenelon M., Gu Z., Wunderling R. (2007) Generating Multiple Solutions for Mixed Integer Programming Problems. In: Fischetti M., Williamson D.P. (eds) Integer Programming and Combinatorial Optimization. IPCO 2007. Lecture Notes in Computer Science, vol 4513. Springer, Berlin, Heidelberg

Solving many scenarios

In [1] a problem is described:

Select 2 teams of 6 players from a population of 24 players such that the average ELO rating of each team is a close as possible. 

It came as a surprise to me, given some random data for the ratings, I was always able to find two teams with exactly the same average rating. When we try this for say 1,000 cases, we have to solve 1,000 independent scenarios, each of them solving a small MIP model. It is interesting to see how we can optimize this loop using GAMS.

Approach	Description	Elapsed Time mm:ss
A. Standard loop	Solve 1,000 models loop(k, r(i) = round(normal(1400,400)); solve m minimizing z using mip; trace(k,j) = avg.l(j); trace(k,'obj') = z.l; );	12:12
B. Optimized loop	Reduce printing to listing file and use DLL interface. m.solvelink=5; m.solprint=2;	3:33
C. Scenario solver	Solve 1,000 scenarios by updating model. Solver threads: 1. solve m min z using mip scenario dict;	1:32
D. Scenario solver	Tell MIP solver to use 4 threads m.threads=4;	2:19
E. Asynchronous scenario solver	Each asynchronous solve calls scenario solver with 250 scenarios m.solveLink = 3; loop(batch, ksub(k) = batchmap(batch,k); solve m min z using mip scenario dict; h(batch) = m.handle; ); Note that these solves operate asynchronously.	0:25
F. Combine into one problem	Add index \(k\) to each variable and equation and solve as one big MIP (see below for details). Use 4 threads.	7:22

The standard loop is the most self-explanatory. But we incur quite some overhead. In each cycle we have:

1. GAMS generates the model and prints equation and column listing
2. GAMS shuts down after saving its environment
3. The solver executable is  called
4. GAMS restarts and reads back the environment
5. GAMS reads the solution and prints it

The optimized loop will keep GAMS in memory and calls the solver as a DLL instead of an executable. In addition printing is omitted. GAMS is still generating each model, and a solver is loading and solving the model from scratch.

The scenario solver will keep the model stored inside the solver and applies updates. In essence the GAMS loop is moved closer to the solver. To enable the scenario solver, we calculate all random ratings in advance:

    rk(k,i) = round(normal(1400,400));

As these are very small MIP models, adding solver threads to solve each model is not very useful. In our case it was even slightly worsening things. For small models most of the work is sequential (presolve, scaling, preprocessing etc) and there is also some overhead in doing parallel MIP (fork, wait, join).

Approach E is to setup asynchronous scenario solves. We split the 1,000 scenarios in 4 batches of 250 scenarios. We then solve each batch in parallel and use the scenario solver to solve a batch using 1 solver thread. This more coarse-grained parallelism is way more effective than using multiple threads inside the MIP solver. With this approach we can solve on average 40 small MIP models per second, which I think is pretty good throughput. A disadvantage is that the tools for this are rather poorly designed and the setup for this is quite cumbersome: different loops are needed to launch solvers asynchronously and retrieving results after threads terminate.

There is still some room for further improvements. Using parallel scenario solves we have to assign scenarios to threads in advance. It is possible that one or more threads finish their workload early. This type of starvation is difficult prevent with parallel scenario solves (basically the scenario solver should become more capable and be able to handle multiple threads).

Finally, I also tried to combine all scenarios into one big MIP model. I.e. we have:

Single scenario	Combined model
\[\begin{align}\min\>& \color{DarkRed} z \\ & \sum_j \color{DarkRed} x_{i,j} \le 1 && \forall i\\ & \sum_i \color{DarkRed} x_{i,j} = \color{DarkBlue} n && \forall j \\ & \color{DarkRed}{\mathit{avg}}_j = \frac{\displaystyle \sum_i \color{DarkBlue} r_i \color{DarkRed} x_{i,j}}{\color{DarkBlue} n} \\ & - \color{DarkRed} z \le \color{DarkRed}{\mathit{avg}}_2 - \color{DarkRed}{\mathit{avg}}_1 \le \color{DarkRed} z \\ & \color{DarkRed}x_{i,j} \in \{0,1\}\end{align}\]	\[\begin{align}\min\>& \color{DarkRed} z_{total} = \sum_k \color{DarkRed} z_k \\ & \sum_j \color{DarkRed} x_{i,j,k} \le 1 && \forall i,k\\ & \sum_i \color{DarkRed} x_{i,j,k} = \color{DarkBlue} n && \forall j,k \\ & \color{DarkRed}{\mathit{avg}}_{j,k} = \frac{\displaystyle \sum_i \color{DarkBlue} r_{i,k} \color{DarkRed} x_{i,j,k}}{\color{DarkBlue} n} \\ & - \color{DarkRed} z_k \le \color{DarkRed}{\mathit{avg}}_{2,k} - \color{DarkRed}{\mathit{avg}}_{1,k} \le \color{DarkRed} z_k \\ & \color{DarkRed}x_{i,j,k} \in \{0,1\}\end{align}\]
Equations: 30 Variables: 51 Binary variables: 48	Equations: 30,000 Variables: 51,000 Binary variables: 48,000

The combined model is a large MIP model. It is faster than our first loop (too much overhead in the looping). But as soon we get the overhead under control, we see again that solving \(K=1,000\) small models is better than solving one big models that is \(K\) times as large.

It is noted that this combined model can be viewed as having a block-diagonal structure. After reordering the rows and the columns, the LP matrix can look like:

Structure of the combined model (after reordering)

LP solvers do not really try to exploit this structure and just look at it as a big, sparse matrix.

This looks like a somewhat special case: many, independent, very small MIP models. However, I have been involved in projects dealing with multi-criteria design problems that had similar characteristics.

Conclusions:

• The end result: even for 1000 random scenarios, we can find in each case two teams that have exactly the same average ELO rating.
• Solving many different independent scenarios may require some attention to achieve best performance. 

References

1. Selecting Chess Players, https://yetanothermathprogrammingconsultant.blogspot.com/2018/11/selecting-chess-players.html

Selecting Chess Players

In [1] a simple problem was posted:

• We have a population of \(N=24\) players, each with an ELO rating \(r_i\)
• We need to select \(2 \times 6\) players for 2 teams (each team has \(n=6\) members).
• We want to minimize the difference in average ELO ratings of the teams.

The poster asked for an algorithm. But, of course, this looks like a problem we can solve as a mathematical programming model. 

First I generated some random data:

----     11 PARAMETER r  ELO rating

player1  1275,    player2  1531,    player3  1585,    player4   668,    player5  1107,    player6  1011
player7  1242,    player8  1774,    player9  1096,    player10 1400,    player11 1036,    player12 1538
player13 1135,    player14 1206,    player15 2153,    player16 1112,    player17  880,    player18  850
player19 1528,    player20 1875,    player21  939,    player22 1684,    player23 1807,    player24 1110

I have no idea if these numbers are realistic or not.

It make sense to look at this from an assignment problem point of view. It is amazing how often this concept is encountered in modeling. So we define:\[x_{i,j}=\begin{cases} 1 & \text{if player $i$ is assigned to team $j$}\\ 0 & \text{otherwise}\end{cases}\]

A high-level model can look like:

High-level Model

\[\begin{align}\min\>& | \color{DarkRed}{\mathit{avg}}_2 - \color{DarkRed}{\mathit{avg}}_1 | \\ & \sum_j \color{DarkRed} x_{i,j} \le 1 && \forall i\\ & \sum_i \color{DarkRed} x_{i,j} = \color{DarkBlue} n && \forall j \\ & \color{DarkRed}{\mathit{avg}}_j = \frac{\displaystyle \sum_i \color{DarkBlue} r_i \color{DarkRed} x_{i,j}}{\color{DarkBlue} n}  \\ & \color{DarkRed}x_{i,j} \in \{0,1\}\end{align} \]

As you can see, this model is largely an assignment problem plus some average calculations.

Notes:

• The absolute value is easily linearized in different ways:
• Bounding \[\begin{align} \min\> & z \\ & -z \le \mathit{avg}_2-\mathit{avg}_1\le z\end{align}\]
• Variable splitting: \[\begin{align} \min\> & z^{+}+z^{-} \\ & z^{+}-z^{-} = \mathit{avg}_2-\mathit{avg}_1 \\ & z^{+},z^{-}\ge 0 \end{align}\]
• Removing symmetry. We can require that the average rating of team 1 is not lower than of team 2. Now we just can minimize difference: \[\begin{align} \min\> &  \mathit{avg}_1 - \mathit{avg}_2\\ &  \mathit{avg}_1 \ge \mathit{avg}_2 \end{align}\]
• We can use the sum instead of the average

Surprisingly, the solution looks like:

----     43 VARIABLE x.L  assignment

               team1       team2

player1        1.000
player2                    1.000
player4        1.000
player5                    1.000
player6                    1.000
player7        1.000
player8        1.000
player9        1.000
player10                   1.000
player11                   1.000
player17       1.000
player18                   1.000


----     43 VARIABLE avg.L  average rating of team

team1 1155.833,    team2 1155.833


----     43 PARAMETER report  solution report

               team1       team2

player1     1275.000
player2                 1531.000
player4      668.000
player5                 1107.000
player6                 1011.000
player7     1242.000
player8     1774.000
player9     1096.000
player10                1400.000
player11                1036.000
player17     880.000
player18                 850.000
sum         6935.000    6935.000
avg         1155.833    1155.833

We achieved a perfect match!

The probability of this must be somewhat low. Well, no. If we try this 10 times with different random \(r_i\), we get 10 times a perfect match.

----     50 PARAMETER trace  results for each solve

           avg1        avg2

k1     1155.833    1155.833
k2     1583.333    1583.333
k3     1385.333    1385.333
k4     1258.500    1258.500
k5     1423.167    1423.167
k6     1491.833    1491.833
k7     1262.167    1262.167
k8     1736.167    1736.167
k9     1514.167    1514.167
k10    1483.667    1483.667

Using a solve loop of length 100 gives the same result. It looks that we almost always can form two teams with equal average ELO rating. I suspect it will be very difficult to derive anything analytically about the probability of not being able to find a perfect match. I was surprised by these results.

Discussion

Often, people with a Computer Science/programming background immediately think about algorithms instead of mathematical models. They miss out on a paradigm that can be very powerful and efficient  (in terms of time needed to design, implement and maintain an algorithm or model). This model was thought out, implemented and tested in less than 20 minutes (including finding out what this ELO is). I am sure developing some special purpose algorithm will take much more time. In addition, for this model, the solver will find proven optimal solutions while developing an algorithm yourself will likely result in some heuristic without any concept of optimality.

References

1. Team matchmaking algorithm based on ELO, https://stackoverflow.com/questions/53119389/team-matchmaking-algorithm-based-on-elo

Quadratic Programming with Binary Variables

Quadratic Programming models where the quadratic terms involve only binary variables are interesting from a modeling point view: we can apply different reformulations.

Let's have a look at the basic model:

0-1 Unconstrained Non-convex Quadratic Programming
\[\begin{align}\min\>& \color{DarkRed}x^{T} \color{DarkBlue}Q \color{DarkRed}x + \color{DarkBlue} c^{T}\color{DarkRed}x\\ & \color{DarkRed}x_i \in \{0,1\}\end{align} \]

Only if the matrix \(Q\) is positive definite we have a convex problem. So, in general, the above problem is non-convex. To keep things simple, I have no constraints and no additional continuous variables (adding those does not not really change the story).

Test data

To play a bit a with this model, I generated random data:

• Q is about 25% dense (i.e. about 75% of the entries \(q_{i,j}\) are zero). The nonzero entries are drawn from a uniform distribution between -100 and 100.
• The linear coefficients are uniformly distributed \(c_i \sim U(-100,100)\).
• The size of the model is: \(n=75\) (i.e. 75 binary variables). This is relative small, so the hope is we can solve this problem quickly. As we shall see the results will be very mixed.

Local MINLP solvers

Many local MINLP solvers tolerate non-convex problems, but they will not produce a global optimum. So we see:

Solver	Objective	Time	Notes
SBB	-7558.6235	0.5	Local optimum
Knitro	-7714.5721	0.4	Id.
Bonmin	-7626.7975	1.3	Id.

All solvers used default settings and timings are in seconds. It is not surprising that these local solvers find different local optima. For all solvers, the relaxed solution was almost integer and just a few nodes were needed to produce an integer solution. This looks promising. Unfortunately, we need to contain our optimism.

Global MINLP Solvers

Global MINLP solvers are in theory well-equipped to solve this model. Unfortunately, they are usually quite slow. For this example, we see a very wide performance range:

Solver	Objective	Time	Notes
Baron	-7760.1771	82
Couenne	-7646.5987	>3600	Time limit, gap 25%
Antigone	-7760.1771	252

Couenne is struggling with this model. Baron and Antigone are doing quite good on this model. We can further observe that the local solvers did not find the global optimal solution.

MIQP Solvers

If we just use an MIQP solver, we may get different results, depending on the solvers. If the solver expects a convex model, it will refuse to solve the model. Other solvers may use some automatic reformulation. Let's try a few:

Solver	Objective	Time	Notes
Mosek			Q not positive definite
Cplex	-7760.1771	27	Automatically reformulated to a MIP
Gurobi	-7760.1760	>9999	Time limit, gap 37% (Gurobi 8.0)

Most solvers have options to influence what reformulations are applied. Here we ran with default settings. MIQP solvers tend to have many options, including those that influence automatic reformulations. I just used defaults, assuming "the solver knows best what to do".

The global MINLP solvers Baron and Antigone did not do bad at all. It is noted that Gurobi 8.1 has better MIQP performance [2] (hopefully it does much better than what we see here). It is noted that we can force Gurobi to linearize the MIQP model using the solver option preqlinearize 1, and in that case it solves fast.

Perturb Diagonal

For borderline non-convex models, it is not unusual to see messages from a quadratic solver that the diagonal of \(Q\) has been perturbed to make the problem convex. Here we do the same thing in the extreme [1].

Background: a matrix \(Q\) is positive definite (positive semi-definite) if all eigenvalues \(\lambda_i \gt 0\) (\(\lambda_i\ge 0\)). If there are negative eigenvalues, we can conclude \(\min x^TQx\) is a non-convex problem. From this we see that the sign of the smallest eigenvalue \(\lambda_{min}\) plays an important role.

To calculate the smallest eigenvalue we first have to make \(Q\) symmetric (otherwise we would get complex eigenvalues). This can easily be done by replacing \(Q\) by \(0.5(Q^T+Q)\). This operation will not change the values of the quadratic form \(x^TQx\).

If after calculating the smallest eigenvalue \(\lambda_{min}\), we observe \(\lambda_{min} \lt 0\), we can form  \[\widetilde{Q} = Q - \lambda_{min} I \] Note that we actually add a positive number to the diagonal as  \(\lambda_{min}\lt 0\). To compensate we need to add to the objective a linear term of the form \[\sum_i  \lambda_{min} x_i^2 = \sum_i  \lambda_{min} x_i\] (for binary variables we have \(x_i^2=x_i\)). With this trick, we made the problem convex.

For our data set we have \(\lambda_{min} = -353.710\). To make sure we are becoming convex, I added a very generous tolerance: \(\lambda_{min}-1\). So I used: \(\widetilde{Q} = Q - (\lambda_{min}-1) I \).

Convexified Model
\[\begin{align}\min\>& \color{DarkRed} x^T \left( \color{DarkBlue} Q - (\lambda_{min}-1) I \right) \color{DarkRed} x + \left(\color{DarkBlue} c + (\lambda_{min}-1) \right)^T \color{DarkRed} x \\ & \color{DarkRed}x_i \in \{0,1\}\end{align} \]

With this reformulation we obtained a convex MIQP. This means for instance that a solver like Mosek is back in play, and that local solvers will produce global optimal solutions. Let's try:

Solver	Objective	Time	Notes
Mosek	-7760.1771	725
Knitro	-7760.1771	2724	Node limit, gap: 3%
Bonmin	-7760.1771	>3600	Time limit, gap: 6%

These results are a little bit slower than I expected, especially when comparing to the performance of the global solvers Baron and Antigone. These results are also much slower than the first experiment with local solvers where we found integer feasible local solutions very fast.

Note. We could have started by removing all diagonal elements from \(Q\) and moving them into \(c\). This is again based on the fact that \(x_i^2 = x_i\).  I did not do this step in this experiment.

Linearization

We already saw that some solvers (such as Cplex) apply a linearization automatically. Of course we can do this ourselves.

The first thing we can do to help things along is to make \(Q\) a triangular matrix. We can do this by: \[\tilde{q}_{i,j} = \begin{cases} q_{i,j}+q_{j,i} & \text{if $i \lt j$} \\ q_{i,j} & \text{if $i=j$}\\ 0 & \text{if $i \gt j$}\end{cases}\]

The next thing to do is to introduce variables \(y_{i,j} = x_i x_j\). This binary multiplication can be linearized easily: \[\begin{align} & y_{i,j} \le x_i \\ & y_{i,j} \le x_j \\ & y_{i,j} \ge x_i + x_j -1 \\ & 0 \le y_{i,j} \le 1 \end{align}\] In the actual model, we can skip a few of these inequalities by observing in which directions the objective pushes variables \(y_{i,j}\) (see [1]).

Linearized Model

\[\begin{align} \min\>& \sum_{i,j|i\lt j} \color{DarkBlue}{\tilde{q}}_{i,j} \color{DarkRed} y_{i,j} + \sum_i  \left( \color{DarkBlue} {\tilde{q}}_{i,i} + \color{DarkBlue} c_i \right) \color{DarkRed} x_i  \\ &  \color{DarkRed}y_{i,j} \le \color{DarkRed}x_i && \forall i\lt j, \color{DarkBlue} {\tilde{q}}_{i,j} \lt 0 \\ &  \color{DarkRed}y_{i,j} \le \color{DarkRed}x_j && \forall i\lt j, \color{DarkBlue} {\tilde{q}}_{i,j} \lt 0 \\ &  \color{DarkRed}y_{i,j} \ge \color{DarkRed}x_i +\color{DarkRed}x_j -1 && \forall i\lt j, \color{DarkBlue} {\tilde{q}}_{i,j} \gt 0 \\ &  0 \le \color{DarkRed}y_{i,j} \le 1 &&  \forall i\lt j, \color{DarkBlue} {\tilde{q}}_{i,j} \ne 0 \\ &  \color{DarkRed}x_i \in \{0,1\} \\  \end{align} \]

This model does not care whether the original problem is convex or not. Let's see how this works:

Solver	Objective	Time	Notes
Cplex	-7760.1771	41
CBC	-7760.1771	6488

It is known this MIP is not so easy to solve. A commercial MIP solver may be required to get good solution times. Here we see that Cplex (commercial) is doing much better than CBC (open source).

Conclusion

The problem under consideration: an unconstrained MIQP with just \(n=75\) binary variables, is not that easy to solve. The overall winning strategy is to use a commercial MIP solver against a manually or automatically reformulated MIP model. Solving the MIQP directly is just very difficult for many solvers. The global solver Baron does a surprisingly good job. It is noted that if the data or the problem size changes, these performance figures may shift (a lot).

Update

An earlier version of this post had a much slower performance for Cplex MIQP. When rerunning this, I could not reproduce this, so this must have been a note taking error on my side (I suspect I was comparing with a result with \(n=100\)). Now, Cplex MIQP and Cplex MIP on the manually reformulated model perform comparable. My faith in Cplex automatic reformulation is fully restored (and my faith in my note taking skills further reduced). Apologies for this.

References

1. Billionnet, A. and Elloumi, S., Using a mixed integer quadratic programming solver for the unconstrained quadratic 0-1 problem. Math. Program. 109 (2007) pp. 55–68
2. http://yetanothermathprogrammingconsultant.blogspot.com/2018/10/gurobi-81.html

Strange objective

In [1], a question was posted how to use the \(\mathit{sign}()\) function in the SCIP solver. The problem to solve is

argmax(w) sum(sign(Aw) == sign(b)) 

This is a strange objective. Basically: find \(w\), with \(v=Aw\) such that we maximize the number of  \(v_i\) having the same sign as \(b_i\). I have never seen such an objective.

As \(A\) and \(b\) are constants, we can precompute \[ \beta_i = \mathrm{sign}(b_i)\] This simplifies the situation a little bit (but I will not need it below).

A different way to say "\(v_i\) and \(b_i\) have the same sign" is to state: \[ v_i b_i > 0 \] I assumed here \(b_i \ne 0\). Similarly, the constraint \( v_i b_i < 0\) means: "\(v_i\) and \(b_i\) have the opposite sign."

If we introduce binary variables: \[\delta_i = \begin{cases} 1 & \text{if $ v_i b_i > 0$}\\ 0 & \text{otherwise}\end{cases}\] a model can look like: \[\begin{align} \max & \sum_i \delta_i \\ &\delta_i =1 \Rightarrow \sum_j a_{i,j} b_i w_j > 0 \\ & \delta_i \in \{0,1\}\end{align}\] The implication can be implemented using indicator constraints, so we have now a linear MIP model.

Notes:

• I replaced the \(\gt\) constraint by \(\sum_j a_{i,j} b_i w_j \ge 0.001\) 
• If the \(b_i\) are very small or very large we can replace them by \(\beta_i\), i.e. \(\sum_j a_{i,j} \beta_i w_j \gt 0\)
• The case where some \(b_i=0\) is somewhat ignored here. In this model, we assume \(\delta_i=0\) for this special case. 
• We can add explicit support for  \(b_i=0\) by:  \[\begin{align} \max & \sum_i \delta_i \\ &\delta_i =1 \Rightarrow \sum_j a_{i,j} b_i w_j > 0 && \forall i | b_i\ne 0 \\ & \delta_i =1 \Rightarrow \sum_j a_{i,j} w_j = 0 && \forall i | b_i = 0  \\ & \delta_i \in \{0,1\}\end{align}\]
• We could model this with binary variables or SOS1 variables. Binary variables require big-M values. It is not always easy to find good values for them. The advantage of indicator constraints is that they allow an intuitive formulation of the problem while not using big-M values. 
• Many high-end solvers (Cplex, Gurobi, Xpress, SCIP) support indicator constraints. Modeling systems like AMPL also support them.

Test with small data set

Let's do a test with a small random data set.

----     17 PARAMETER a  random matrix

             j1          j2          j3          j4          j5

i1       -0.657       0.687       0.101      -0.398      -0.416
i2       -0.552      -0.300       0.713      -0.866 4.213380E-4
i3        0.996       0.157       0.982       0.525      -0.739
i4        0.279      -0.681      -0.500       0.338      -0.129
i5       -0.281      -0.297      -0.737      -0.700       0.178
i6        0.662      -0.538       0.331       0.552      -0.393
i7       -0.779       0.005      -0.680       0.745      -0.470
i8       -0.428       0.188       0.445       0.256      -0.072
i9       -0.173      -0.765      -0.372      -0.907      -0.323
i10      -0.636       0.291       0.121       0.540      -0.404
i11       0.322       0.512       0.255      -0.432      -0.827
i12      -0.795       0.283       0.091      -0.937       0.585
i13      -0.854      -0.649       0.051       0.500      -0.644
i14      -0.932       0.170       0.242      -0.221      -0.283
i15      -0.514      -0.507      -0.739       0.867      -0.240
i16       0.567      -0.400      -0.749       0.498      -0.862
i17      -0.596      -0.990      -0.461 -2.97050E-4      -0.697
i18      -0.652      -0.339      -0.366      -0.356       0.928
i19       0.987      -0.260      -0.254       0.544      -0.207
i20       0.826      -0.761       0.471      -0.889       0.153
i21      -0.897      -0.988      -0.198       0.040       0.258
i22      -0.549      -0.208      -0.448      -0.695       0.873
i23      -0.155      -0.731      -0.228      -0.251      -0.463
i24       0.897      -0.622      -0.405      -0.851      -0.197
i25      -0.797      -0.232      -0.352      -0.616      -0.775


----     17 PARAMETER b  random rhs

i1   0.193,    i2   0.023,    i3  -0.910,    i4   0.566,    i5   0.891,    i6   0.193,    i7   0.215,    i8  -0.275
i9   0.188,    i10  0.360,    i11  0.013,    i12 -0.681,    i13  0.314,    i14  0.048,    i15 -0.751,    i16  0.973
i17 -0.544,    i18  0.351,    i19  0.554,    i20  0.865,    i21 -0.598,    i22 -0.406,    i23 -0.606,    i24 -0.507
i25  0.293


----     17 PARAMETER beta  sign of b

i1   1.000,    i2   1.000,    i3  -1.000,    i4   1.000,    i5   1.000,    i6   1.000,    i7   1.000,    i8  -1.000
i9   1.000,    i10  1.000,    i11  1.000,    i12 -1.000,    i13  1.000,    i14  1.000,    i15 -1.000,    i16  1.000
i17 -1.000,    i18  1.000,    i19  1.000,    i20  1.000,    i21 -1.000,    i22 -1.000,    i23 -1.000,    i24 -1.000
i25  1.000


----     53 VARIABLE w.L  

j1 -0.285,    j2 -0.713,    j3 -0.261,    j4 -0.181,    j5 -0.630


----     53 PARAMETER v  sum(j, a(i,j)*w(j))

i1   0.005,    i2   0.342,    i3  -0.282,    i4   0.556,    i5   0.498,    i6   0.256,    i7   0.557,    i8  -0.129
i9   1.059,    i10  0.099,    i11  0.076,    i12 -0.197,    i13  1.008,    i14  0.299,    i15  0.695,    i16  0.771
i17  1.435,    i18  0.003,    i19  0.002,    i20  0.249,    i21  0.843,    i22 -0.002,    i23  0.962,    i24  0.571
i25  1.084


----     53 VARIABLE delta.L  

i1  1.000,    i2  1.000,    i3  1.000,    i4  1.000,    i5  1.000,    i6  1.000,    i7  1.000,    i8  1.000
i9  1.000,    i10 1.000,    i11 1.000,    i12 1.000,    i13 1.000,    i14 1.000,    i16 1.000,    i18 1.000
i19 1.000,    i20 1.000,    i22 1.000,    i25 1.000


----     53 VARIABLE z.L                   =       20.000  objective variable

This means, for this 25 row problem we can find \(w\)'s such that 20 rows yield the same sign as \(b_i\).

References

1. SCIP What is the function for sign?, https://stackoverflow.com/questions/53030430/scip-what-is-the-function-for-sign

Gurobi 8.1

Quite some improvements in MIQP performance. Of course the smaller improvements in other model types also help: over time these things add up to substantial performance gains.

Announcement

Gurobi is pleased to announce the release of Gurobi Version 8.1. This latest version improves the overall performance of Gurobi Optimizer, and adds enhancements to Gurobi Instant Cloud, including support for Microsoft Azure® and for the latest Amazon Web Services® machines, and more.

Version 8.1 demonstrates our commitment to delivering the new features our users request, and includes:

Performance Improvements

Gurobi Optimizer v8.1 continues to push the envelope of solver speed and performance. The overall v8.1 performance improvements versus v8.0 include:

MIQP 

• More than a factor of 2.8x faster overall.
• More than a factor of 6x faster on difficult models that take more than 100 seconds to solve.

MIQCP

• 38% faster overall.
• 92% faster on difficult models that take more than 100 seconds to solve.

LP

• 2.9% faster overall in default settings.
• 6.5% faster on difficult models that take more than 100 seconds to solve.

LP barrier

• 4.4% faster overall.
• 11% faster on difficult models that take more than 100 seconds to solve.

LP dual simplex

• 4.2% faster overall.
• 10.5% faster on difficult models that take more than 100 seconds to solve.

---

Enhancements

• Gurobi Instant Cloud now supports Microsoft Azure®: Instant Cloud users can now use Microsoft Azure, in several regions.
• Gurobi Instant Cloud adds faster and more powerful machines on Amazon EC2®: The new version supports c5, r5 and z1 instance types.
• New Q matrix linearization for MIQP and MIQCP models: We added a new Q matrix linearization approach in presolve. This new option can be chosen by setting parameter PreQLinearize to the new value of 2.
• Improved Mac Installation Package: Users no longer need to install Xcode to perform the installation.
• Support for Python 3.7: We have added support for Python 3.7 on Windows, Linux and Mac platforms.
• A callback function for multi-objective optimization: We now let users terminate optimization for individual objectives for multi-objective MIP models.

To learn more about all of the new features and improvements, visit What's New in Gurobi 8.1.

The Muffin Problem

We are asked to split \(m=5\) muffins between \(s=3\) students, such that each student gets in total \[\frac{m}{s} = \frac{5}{3}\] worth of muffins [1]. From [2] we see two possible ways of doing this:

Allocation 1 (from [2])

Allocation 2 (from [2])

(I believe Proc means Protocol). The problem is to find a way to divide the muffins such that the smallest piece is maximized.

There is a nice and simple MIP formulation for this. Let's define \(x_{i,j} \in [0,1]\) as the fraction of muffin \(i\) assigned to student \(j\). Also we need: \[\delta_{i,j} = \begin{cases} 1 & \text{if $x_{i,j} \gt 0$} \\ 0 & \text{if $x_{i,j}=0$}\end{cases}\] Then we can write:

Muffin Problem

\[\begin{align}\max\> & \color{DarkRed} z \\ & \sum_i \color{DarkRed} x_{i,j} = \color{DarkBlue} {\frac{m}{s}} && \forall j\\ & \sum_j \color{DarkRed} x_{i,j} = 1  && \forall i\\ & \color{DarkRed} \delta_{i,j} = 0 \Rightarrow \color{DarkRed} x_{i,j} = 0 \\ & \color{DarkRed} \delta_{i,j} = 1 \Rightarrow \color{DarkRed} z \le \color{DarkRed} x_{i,j} \\ & 0 \le \color{DarkRed} x_{i,j} \le 1\\ & \color{DarkRed} \delta_{i,j} \in \{0,1\}\end{align}\]

The objective takes care of \(x_{i,j}=0 \Rightarrow \delta_{i,j}=0\). Some MIP solvers allow us to use the implications directly (as so-called indicator constraints). For others we need to reformulate. It is not difficult to rewrite them as inequalities:

Implication	Inequality
\[\color{DarkRed} \delta_{i,j} = 0 \Rightarrow \color{DarkRed} x_{i,j} = 0 \]	\[\color{DarkRed} x_{i,j} \le \color{DarkRed} \delta_{i,j}\]
\[\color{DarkRed} \delta_{i,j} = 1 \Rightarrow \color{DarkRed} z \le \color{DarkRed} x_{i,j} \]	\[\color{DarkRed} z \le \color{DarkRed} x_{i,j}+ (1-\color{DarkRed} \delta_{i,j})\]

This is similar to what is proposed in [1] (they use \(y_{i,j} = 1-\delta_{i,j}\)) and somewhat simpler than the approach used in [3].

The results are:

----     26 VARIABLE x.L  fraction of muffin assigned to student

           student1    student2    student3

muffin1       0.500                   0.500
muffin2       0.583       0.417
muffin3                   0.417       0.583
muffin4       0.583       0.417
muffin5                   0.417       0.583


----     26 VARIABLE d.L  indicator for nonzero x

           student1    student2    student3

muffin1       1.000                   1.000
muffin2       1.000       1.000
muffin3                   1.000       1.000
muffin4       1.000       1.000
muffin5                   1.000       1.000


----     26 VARIABLE z.L                   =        0.417  smallest nonzero x

If student1 arrives early and confiscates muffin1, we can fix \(x_{\text{muffin1},\text{student1}}=1\). With this we can reproduce the first solution:

----     28 VARIABLE x.L  fraction of muffin assigned to student

           student1    student2    student3

muffin1       1.000
muffin2                   1.000
muffin3       0.333       0.667
muffin4                               1.000
muffin5       0.333                   0.667


----     28 VARIABLE z.L                   =        0.333  smallest nonzero x

A solution for 7 muffins and 5 students can look like:

----     26 VARIABLE x.L  fraction of muffin assigned to student

           student1    student2    student3    student4    student5

muffin1       0.667       0.333
muffin2       0.333                   0.667
muffin3       0.400       0.600
muffin4                               0.333       0.333       0.333
muffin5                   0.467                               0.533
muffin6                                           0.467       0.533
muffin7                               0.400       0.600


----     26 VARIABLE z.L                   =        0.333  smallest nonzero x

Not all problems are super easy to solve to proven optimality. E.g. with 11 muffins and 9 students, I had to spend several minutes. As usual the solver quickly found the optimal solution, but proving optimality was not so quick. There is lots of symmetry in the model. That may be something to exploit.

References

1. Guangiqi Cui, John Dickerson, Naveen Durvasula, William Gasarch, Erik Metz, Jacob Prinz, Naveen Raman, Daniel Smolyak, Sung Hyun Yoo, The Muffin Problem, 13 Mar 2018, https://arxiv.org/pdf/1709.02452.pdf
2. https://www.cs.umd.edu/~gasarch/muffintalk.pdf
3. https://math.stackexchange.com/questions/2958179/how-to-prove-that-1-3-is-the-optimal-solution-for-the-muffin-problem-with-5-stud
4. NRC (Dutch newspaper), https://www.nrc.nl/nieuws/2018/09/14/hoe-vijf-muffins-tot-een-diep-wiskundig-vraagstuk-leidden-a1616534