# Optimal control, inventory management

I am currently working on a simple optimization system which should tell a each time :

• how much liquid I have to inject in my storage from the market ( variable : MS )
• how much liquid I have to withdraw from my storage to meet demand ( variable : SD)
• how much liquid I have to withdraw from my storage to sell on market ( variable : SM)
• how much liquid I have to buy on market to meet demand ( variable : MS)

I have deterministic price for the N time steps coming. I have deterministic demand for the N time steps comming.

Cost associated are :

• Cms = price
• Cmd = price
• Csd = mean of the gaz cost injected previously (1->i , where i is the day of decision) in my storage
• Csm = mean of the gaz cost injected previously (1->i , where i is the day of decision) in my storage

My objective function is to minimize logistic cost.

``````f = sum( Cms*MS + Cmd*MD + Csd*SD - (Price-Csm)*SM), on all time steps.
``````

This problem is non-linaer due to the `Csm` and `Csd` which involves previous decision( my variables)

I am trying to solve it using R (especially `genoud()`) but it is not converging to the global minimum and it is very slow.

So if anyone has an idea on how to reformulate my problem or to compute faster I would be grateful ?

OK I tried to edit my question with a simple code of what I want to do there :

``````# libraries

#rm(list=ls())
#Sys.sleep(1)
library("rgenoud")

# number of periods
Np<-12
# number of variables
Nvars<-4*Np

# dec1 dec2 dec3 dec4
#MD    MS   SD   SM

# initial price stock per unit
Stock0<-23.5

price <- c(29,29,28,26,25,25,23,23,26,27,28,29,29,28,27,26,25,24,23,25,26,27,28,29)
price <- price[1:Np]
price

dem<-c(12,11,9,8,7,6,6,6,7,8,10,11,12,11,9,8,7,6,6,6,7,8,10,11)
dem<-dem[1:Np]
length(dem)

StockMax<-c(75,65,50,40,52,65,73,85,95,100,95,85,75,65,50,40,60,70,75,85,95,100,85,80)
StockMax<-StockMax[1:Np]
StockMin<-StockMax-40
StockIni<-(StockMax[1]-StockMin[1])/2 + StockMin[1]

dem<-c(12,11,9,8,7,6,6,6,7,8,10,11,12,11,9,8,7,6,6,6,7,8,10,11)
dem<-dem[1:Np]

# objective function
logistic<-function(dec,Np,Stock0,StockIni,price,dem,StockMax,StockMin) {
V<-0
Stock0<-Stock0
Cinj<-0.34
Cext<-0.11
V<-numeric(Np)
V2<-numeric(Np)
V1<-StockIni*Stock0

for(i in 1:Np){
V[i]<-(price[i]+Cinj)*dec[4*(i-1)+1]
V0<-mean(c(V1,V[i:1]))
V2[i]<-price[i]*dec[4*(i-1)+1] + (price[i]+Cinj)*dec[4*(i-1)+2] + (Cinj+V0)*dec[4*(i-1)+3] - (price[1]-Cext-V0)*dec[4*(i-1)+4]
}

Resf<-sum(V2)

#  if I don't respect my equalities contraints my objective function value is bad
Z<-numeric(Np)
for(i in 1:Np) {
Z[i]<-dec[4*(i-1)+1]+dec[4*(i-1)+3]
if(Z[i]<=(dem[i]-0.05*dem[i]) || Z[i]>=(dem[i]+0.05*dem[i])) {
Resf<- + 100000
}
}

# if I don't respect my inequalities contraints my objective function is bad

Z1<-numeric(Np)
Z1[1]<-StockIni+dec[2]-dec[3]-dec[4]
if(Z1[1]<=StockMin[i] || Z1[1]>=StockMax[i]) {
Resf <- + 100000
}

for(i in 2:Np) {
Z1[i]<-Z1[i-1]+dec[4*(i-1)+2]-dec[4*(i-1)+3]-dec[4*(i-1)+4]
if(Z1[i]<=StockMin[i] || Z1[i]>=StockMax[i]) {
Resf <- + 100000
}
}

return(Resf)
}

# limit of the box contraints
LB1<-0
UB1<-50
dom<-matrix(0,Nvars,2)
dom[,1]<-LB1
dom[,2]<-UB1
dom

# resolution by genetic algorithm
ans <- genoud(logistic, nvars=Nvars, max=FALSE, pop.size=1000,
max.generations=70, wait.generations=30,
hard.generation.limit=TRUE, starting.values=PopIni, MemoryMatrix=TRUE,
Domains=dom, solution.tolerance=1, data.type.int=TRUE,
BFGS=TRUE,
print.level=2,
Np=Np,
Stock0=Stock0,
price=price,
StockIni=StockIni,
dem=dem,
StockMax=StockMax,
StockMin=StockMin)

# plotting stuffs

ans2<-ans\$par

Res1<-matrix(NA,Np,4)
for(i in 1:Np){
Res1[i,1]<-ans2[4*(i-1)+1]
Res1[i,2]<-ans2[4*(i-1)+2]
Res1[i,3]<-ans2[4*(i-1)+3]
Res1[i,4]<-ans2[4*(i-1)+4]
}

Res1
Res1<-as.data.frame(Res1)
colnames(Res1)<-c("MA","MS","SA","SM")
Res1

Stock1<-numeric(Np+1)
Stock1[1]<-StockIni
for(i in 2:(Np+1)){
Stock1[i]<-Stock1[i-1]+Res1[i-1,2]-Res1[i-1,3]-Res1[i-1,4]
}
Stock1

StockMax2<-c(StockMax[1]+5,StockMax)
StockMin2<-c(StockMin[1]+5,StockMin)

plot(Stock1, col='black', ylim=c(0,100),type='b')
lines(StockMax2,col='red')
lines(StockMin2, col='red')
``````

My prices are cheaper for period 5 to 8 so the result I am expecting is that the solution should not do something stupid like buying when expensive and selling when cheap. And the solution should be a bit robust and quick...

I hope this sample can help

If your objective is quadratic but your constraints are linear (are they?), you could look into QP solvers, e.g. `quadprog::solve.QP`. –  flodel Apr 26 '12 at 17:25