There is a lot going on here.

- Description

There seems to be a problem in the description. "*The max sell/***price** is dependent on the stock level." This seems to be wrong. From the data, it looks like the price is constant, but rather sell and buy limits depend on the inventory levels.

- Time

It is important to get the timing right. Usually, we look at `buy`

and `sell`

as things that happen during period *t* (we call them **flow variables**). `inv`

is a **stock variable**, and is measured at the end of period *t*. To say that `sell[t]`

and `buy[t]`

depend on `inv[t]`

is a bit strange (we are going backward in time). Of course, we can model it and solve it (we solve as simultaneous equations, so we can do these things). But, it may not make sense in the real world. Probably we should look at `inv[t-1]`

in order to change `buy[t]`

and `sell[t]`

.

- Segmenting inventory levels.

We need to split inventory levels into segments. We have the following segments:

```
0%-30%
30%-65%
65%-70%
70%-100%
```

we associate a binary variable with each segment:

```
inventory in [0%-30%] <=> δ[1,t] = 1, all other zero
[30%-65%] δ[2,t] = 1
[65%-70%] δ[3,t] = 1
[70%-100%] δ[4,t] = 1
```

Because we need to do this for all time periods, we slap on an extra index t. Warning: we will associate `δ[k,t]`

with the inventory at the beginning of period t, i.e. `inv[t-1]`

. We can link `δ[k,t]`

to `inv[t-1]`

by changing lower- and upper bounds depending on in which segment we are.

- Bounds on buy/sell

Similar to bounds on the inventory, we have the following upper bounds on buy and sell:

```
segment buy sell
0%-30% 4 4
30%-65% 3 6
65%-70% 2 6
70%-100% 2 8
```

The first step is to develop a mathematical model. There is too much going on here that we can immediately code things up. The mathematical model is our "design". So here we go:

With this, we can develop some R code. Here we use CVXR as a modeling tool and GLPK as an MIP solver.

```
> library(CVXR)
>
> # data
> price = c(12, 11, 12, 13, 16, 17, 18, 17, 18, 16, 17, 13)
> capacity = 25
> max_units_buy = 4
> max_units_sell = 8
>
> # capacity segments
> s <- c(0,0.3,0.65,0.7,1)
>
> # corresponding lower and upper bounds
> invlb <- s[1:(length(s)-1)] * capacity
> invlb
[1] 0.00 7.50 16.25 17.50
> invub <- s[2:length(s)] * capacity
> invub
[1] 7.50 16.25 17.50 25.00
>
> buyub <- c(4,3,2,2)
> sellub <- c(4,6,6,8)
>
> # number of time periods
> NT <- length(price)
> NT
[1] 12
>
> # number of capacity segments
> NS <- length(s)-1
> NS
[1] 4
>
> # Decision variables
> inv = Variable(NT,integer=T)
> buy = Variable(NT,integer=T)
> sell = Variable(NT,integer=T)
> delta = Variable(NS,NT,boolean=T)
>
> # Lag operator
> L = cbind(rbind(0,diag(NT-1)),0)
>
> # optimization model
> problem <- Problem(Maximize(sum(price*(sell-buy))),
+ list(inv == L %*% inv + buy - sell,
+ sum_entries(delta,axis=2)==1,
+ L %*% inv >= t(delta) %*% invlb,
+ L %*% inv <= t(delta) %*% invub,
+ buy <= t(delta) %*% buyub,
+ sell <= t(delta) %*% sellub,
+ inv >= 0, inv <= capacity,
+ buy >= 0, sell >= 0))
> result <- solve(problem,verbose=T)
GLPK Simplex Optimizer, v4.47
120 rows, 84 columns, 369 non-zeros
0: obj = 0.000000000e+000 infeas = 1.200e+001 (24)
* 23: obj = 0.000000000e+000 infeas = 0.000e+000 (24)
* 85: obj = -9.875986758e+001 infeas = 0.000e+000 (2)
OPTIMAL SOLUTION FOUND
GLPK Integer Optimizer, v4.47
120 rows, 84 columns, 369 non-zeros
84 integer variables, 48 of which are binary
Integer optimization begins...
+ 85: mip = not found yet >= -inf (1; 0)
+ 123: >>>>> -8.800000000e+001 >= -9.100000000e+001 3.4% (17; 0)
+ 126: >>>>> -9.000000000e+001 >= -9.100000000e+001 1.1% (9; 11)
+ 142: mip = -9.000000000e+001 >= tree is empty 0.0% (0; 35)
INTEGER OPTIMAL SOLUTION FOUND
> cat("status:",result$status)
status: optimal
> cat("objective:",result$value)
objective: 90
> print(result$getValue(buy))
[,1]
[1,] 3
[2,] 4
[3,] 4
[4,] 3
[5,] 3
[6,] 1
[7,] 0
[8,] 0
[9,] 0
[10,] 4
[11,] 0
[12,] 0
> print(result$getValue(sell))
[,1]
[1,] 0
[2,] 0
[3,] 0
[4,] 0
[5,] 0
[6,] 0
[7,] 8
[8,] 6
[9,] 4
[10,] 0
[11,] 4
[12,] 0
> print(result$getValue(inv))
[,1]
[1,] 3
[2,] 7
[3,] 11
[4,] 14
[5,] 17
[6,] 18
[7,] 10
[8,] 4
[9,] 0
[10,] 4
[11,] 0
[12,] 0
> print(result$getValue(delta))
[,1] [,2] [,3] [,4] [,5] [,6] [,7] [,8] [,9] [,10] [,11] [,12]
[1,] 1 1 1 0 0 0 0 0 1 1 1 1
[2,] 0 0 0 1 1 0 0 1 0 0 0 0
[3,] 0 0 0 0 0 1 0 0 0 0 0 0
[4,] 0 0 0 0 0 0 1 0 0 0 0 0
>
```

So, I think someone owes me a good bottle of cognac for this.