The towers of Hanoi problem [1] is a famous puzzle demonstrating recursion. The task is to move a stack of disks from one peg to another. We can only move one disk at a time, and we need to obey the rule that larger disks can never be on top of a smaller disk. The moves for the 3 disk problem are:
The Wolf, goat, and cabbage problem can be stated as [1]:
A farmer with a wolf, a goat, and a cabbage must cross a river by boat. The boat can carry only the farmer and a single item. If left unattended together, the wolf would eat the goat, or the goat would eat the cabbage. How can they cross the river without anything being eaten?
A long transcontinental flight was a good opportunity to try to attack this problem. Here are some approaches to model this. Not at all a very useful or practical model, but still interesting, I think (although I may be in a small minority here).
In this model, we keep track of the inventory of items (wolf, goat, cabbage). We assume the starting inventory is: all items are on the left bank of the river. The final inventory should be: all items are on the right bank. In this model, I assume the following numbering scheme:
---- 31 SET trip trips trip1 , trip2 , trip3 , trip4 , trip5 , trip6 , trip7 , trip8 , trip9 , trip10 ---- 31 SET dir direction of trip L->R, R->L ---- 31 SET tripDir trip direction combos L->R R->L trip1 YES trip2 YES trip3 YES trip4 YES trip5 YES trip6 YES trip7 YES trip8 YES trip9 YES trip10 YES
I have grid of dimensions H and W of boolean variables. The only constraint is that if a variable is false then at least one of the adjacent variables (top, right, left, bottom, diagonals don't count) must be true. The goal is to minimize the number of true values in the grid.
| High-level model |
|---|
| min |
| Model 1: standard min-cost flow network model |
|---|
| \begin{align}\min& \sum_{(i,j)\in A}\color{darkblue}c_{i,j}\cdot\color{darkred}f_{i,j}\\ & \sum_{j|(j,i)\in A}\color{darkred}f_{j,i} + \color{darkblue}{\mathit{supply}}_i = \sum_{j|(i,j)\in A}\color{darkred}f_{i,j} + \color{darkblue}{\mathit{demand}}_i && \forall i \\ & \color{darkred}f_{i,j} \in [0,\color{darkblue}{\mathit{capacity}}_{i,j}] \end{align} |
This is not, per se, very useful, but sorting a parameter inside a MIP model is not very easy for MIP solvers. Obviously, if you need a sorted parameter in the model, it is better to use a sorting algorithm. But useless models can still be interesting.
I use:
Input: a 1-dimensional parameter with values.
Output: a 1-dimensional variable with the values sorted in ascending order.
We can implement this with a permutation matrix \color{darkred}X, which is a permuted identity matrix. In a MIP context, this becomes a binary variable with some assignment constraints.
| MIP Model for sorting p_i |
|---|
| \begin{align}\min\>&\color{darkred}z=0\\& \sum_i \color{darkred}x_{i,j} = 1&&\forall j\\ & \sum_j \color{darkred}x_{i,j} = 1&&\forall i\\ & \color{darkred}y_i = \sum_j \color{darkred}x_{i,j}\cdot\color{darkblue}p_j\\& \color{darkred}y_i \ge \color{darkred}y_{i-1}\\ & \color{darkred}x_{i,j} \in \{0,1\}\end{align} |
Formulating optimization models inside traditional programming languages such as Python is very popular. The main tool the developers use to make this possible is operator overloading. There are cases, where we can write code that looks somewhat reasonable, is accepted and processed without any warning or error messages, but is total nonsense. It is rather difficult with this approach to make things airtight. Especially error handling. In [1], we see a good example. I have created a small fragment here that illustrates the problem.
Here, I want to revisit a particular model from [1]:
| Model 3: Quadratic Preemptive Model |
|---|
| \begin{align}\max\>&\color{darkred}z_{model3}=\sum_p \color{darkred}z_p \\ & \color{darkred}z_p = \sum_{p',g} \color{darkblue}{\mathit{pref}}_{p,p'}\cdot \color{darkred}{\mathit{assign}}_{p,g}\cdot\color{darkred}{\mathit{assign}}_{p',g} \\ & \color{darkblue}z_{model2}^* \le \color{darkred}z_p & \forall p\\ & \sum_g \color{darkred}{\mathit{assign}}_{p,g} = 1 & \forall p \\ & \sum_p \color{darkred}{\mathit{assign}}_{p,g} = \color{darkblue}{\mathit{groupSize}} & \forall g \\& \color{darkred}{\mathit{assign}}_{p,g} \in \{0,1\}\end{align} |
In optimization models, we often use an aggregate measure in the objective function, such as total profit, the sum of tardiness of jobs, and countrywide GDP. This can lead to particularly bad results for some individuals or groups.
Here is an example I have used on several occasions.
We have P persons. They must be assigned to M groups or teams. For simplicity, we can assume n is a multiple of m, and the group size is \frac{N}{M} Each person p_1 specifies some preferences to be placed in the same group as a person p_2. A negative preference can be used to indicate that I prefer to be in a different group. Find an optimal assignment taking into account these preferences.
The latest version of GAMS contains a replacement of gdx2sqlite. This dumps a GDX file into a SQLite database. It is a tool I use a lot. Here is a comparison using the indus89 model in the GAMS model library:
