The following piece of code works when data is passed as a `1x50 array`

.
(Data is in fact a struct that passes several other parameters too). In the `1x50`

case a `4x1`

array of parameters is returned for each i (the value of `de.nP`

is 600).

However I want to change it so that I can pass a matrix of data say `d`

dates so that the matrix has dimension `dx50`

. This will then return a `4xd`

array for each i.

My question is should I use a cell array or a 3D array to store the values? Seems to me both methods could do the job?

```
for i=1:de.nP
betas(:,i)=NSS_betas(P1(:,i),data);
end
```

Going further into the code I will need to use

```
Params=vertcat(betas,P1);
```

Where `P1`

is a `2x1`

array. So for each date (i) I need to concatenate the contents of P(1) to all the betas for that date.

Will this affect the choice of whether to use cellarray or 3D array?

It seems to me cellarray is better suited to vectorised code (Which is what I am trying to use as much as possible) but 3D array might be easier to use with functions like `vertcat`

?

Here is the whole code

```
mats=[1:50];
mats2=[2 5 10 30];
betaTRUE=[5 -2 5 -5 1 3; 4 -3 6 -1 2 4];
for i=1:size(betaTRUE,1)
yM(i,:)=NSS(betaTRUE(i,:),mats);
y2(i,:)=NSS(betaTRUE(i,:),mats2);
end
dataList=struct('yM',yM,'mats',mats,'model',@NSS,'mats2',mats2,'y2',y2);
de=struct('min',[0; 2.5],'max', [2.5;5],'d',2,'nP',200,'nG',300,'ww',0.1,'F',0.5,'CR',0.99,'R',0,'oneElementfromPm',1);
beta=DElambdaVec(de,dataList,@OF);
function [output]=DElambdaVec(de,data,OF)
P1=zeros(de.d,de.nP);
Pu=zeros(de.d,de.nP);
for i=1:de.d
P1(i,:)=de.min(i,1)+(de.max(i,1)-de.min(i,1))*rand(de.nP,1);
end
P1(:,1:de.d)=diag(de.max);
P1(:,de.d+1:2*de.d)=diag(de.min);
for i=1:de.nP
betas(:,i)=NSS_betas(P1(:,i),data);
end
Params=vertcat(betas,P1);
Fbv=NaN(de.nG,1);
Fbest=realmax;
F=zeros(de.nP,1);
P=zeros(de.nP,1);
for i=1:de.nP
F(i)=OF(Params(:,i)',data);
P(i)=pen(P1(:,i),de,F(i));
F(i)=F(i)+P(i);
end
[Fbest indice] =min(F);
xbest=Params(:,indice);
%vF=vF+vP;
%NaN(de.nG,de.nP);
Col=1:de.nP;
for g=1:de.nG
P0=P1;
rowS=randperm(de.nP)';
colS=randperm(4)';
RS=circshift(rowS,colS(1));
R1=circshift(rowS,colS(2));
R2=circshift(rowS,colS(3));
R3=circshift(rowS,colS(4));
%mutate
Pm=P0(:,R1)+de.F*(P0(:,R2)-P0(:,R3));
%extra mutation
if de.R>0
Pm=Pm+de.r*randn(de.d,de.nP);
end
%crossover
PmElements=rand(de.d,de.nP)<de.CR;
%mPv(MI)=mP(Mi);
if de.oneElementfromPm
Row=unidrnd(de.d,1,de.nP);
ExtraPmElements=sparse(Row,Col,1,de.d,de.nP);
PmElements=PmElements|ExtraPmElements;
end
P0_Elements=~PmElements;
Pu(:,RS)=P0(:,RS).*P0_Elements+PmElements.*Pm;
for i=1:de.nP
betasPu(:,i)=NSS_betas(Pu(:,i),data);
end
ParamsPu=vertcat(betasPu,Pu);
flag=0;
for i=1:de.nP
Ftemp=OF(ParamsPu(:,i)',data);
Ptemp=pen(Pu(:,i),de,F(i));
Ftemp=Ftemp+Ptemp;
if Ftemp<=F(i);
P1(:,i)=Pu(:,i);
F(i)=Ftemp;
if Ftemp < Fbest
Fbest=Ftemp; xbest=ParamsPu(:,i); flag=1;
end
else
P1(:,i)=P0(:,i);
end
end
if flag
Fbv(g)=Fbest;
end
end
output.Fbest=Fbest; output.xbest=xbest; output.Fbv=Fbv;
end
function penVal=pen(mP,pso,vF)
minV=pso.min;
maxV=pso.max;
ww=pso.ww;
A=mP-maxV;
A=A+abs(A);
B=minV-mP;
B=B+abs(B);
C=ww*((mP(1,:)+mP(2,:))-abs(mP(1,:)+mP(2,:)));
penVal=ww*sum(A+B,1)*vF-C;
end
function betas=NSS_betas(lambda,data)
mats=data.mats2';
lambda=lambda;
yM=data.y2';
nObs=size(yM,1);
G= [ones(nObs,1) (1-exp(-mats./lambda(1)))./(mats./lambda(1)) ((1-exp(- mats./lambda(1)))./(mats./lambda(1))-exp(-mats./lambda(1))) ((1-exp(- mats./lambda(2)))./(mats./lambda(2))-exp(-mats./lambda(2)))];
betas=G\yM;
end
```

`1x50`

? What is the change you want? What are the essential parts of the code? what do you mean by 'This will then return a 4xd array for each i.' What is`i`

in that case? What are the consequences on that piece of code if you feed it a`dx50`

input? I didn't ask for full code, just to clarify what you want.. if you expect answers, make it easy on the answerers.. – Gunther Struyf Oct 15 '12 at 16:52