I would like to solve for a matrix possessing predetermined row and column totals that most closely resembles a second predetermined matrix possessing the same properties (but possibly with different row/column totals).

So, both matrices must satisfy the following: All elements of must be in the range [0,1].

Any element with a column number less than row number must be 0 in the solution.

Any element with column number greater than row number + 2 must be 0.

So starting with something like this:

```
0.07 0.17 0.47 0.29
0.07 0.1 0.14 0 0.31
0 0.07 0.18 0.07 0.32
0 0 0.15 0.04 0.19
0 0 0 0.18 0.18
```

I would like to minimize the ‘distance’ to this:

```
0.10 0.21 0.37 0.32
0.10 0.11 0.12 0 0.33
0 0.10 0.13 0.10 0.33
0 0 0.12 0.09 0.21
0 0 0 0.13 0.13
```

Such that the original row and column totals from the first matrix are preserved. I would be defining the distance here to be the sum of squared differences between the ith, jth entries in each matrix, but if this is an issue for some reason I would be Ok with using some other measure.

So far I have been trying to do this using solnp in the Rsolnp package like this:

```
rowVals<-c(.31,.32,.19,.18)
colVals<-c(.07,.17,.47,.29)
In<-c(.07,.15,.1,.18,.04,.14,.07)
tar<-c(.1,.11,.12,0,0,.1,.13,.1,0,0,.12,.09,0,0,0,.13)
tar<-matrix(tar,byrow=T,nrow=4)
makeMat <- function(x,n) {
## first and last element of diag are constrained by row/col sums
diagVals <- c(colVals[1],x[1:(n-2)],rowVals[n])
## set up off-diagonals 2,3,4,5,6
sup2Vals <- x[(n-1):(2*n-3)]
sup3Vals <- x[(2*n-2):(3*n-5)]
## set up matrix
m <- diag(diagVals)
m[row(m)==col(m)-1] <- sup2Vals
m[row(m)==col(m)-2] <- sup3Vals
m
}
##objective function
fn<-function(inpt, targt, n, ...){
x<-makeMat(inpt, n=n)
y<-targt
z<-sum((x-y)^2)
z
}
##equality constraint function
eq<-function(x,...){c(rowSums(makeMat(x,length(rowVals))),colSums(makeMat(x,length(colVals))))}
##row/column constraints
eqB<-c(rowVals, colVals)
opt1<-solnp(pars = In, fun = fn, eqfun = eq, eqB = eqB, LB = rep(0,7), targt = tar, n=4)
```

However, when I try to solve I am getting this error:

```
solnp-->Redundant constraints were found. Poor
solnp-->intermediate results may result.Suggest that you
solnp-->remove redundant constraints and re-OPTIMIZE
Iter: 1 fn: 0.0116 Pars: 0.07000 0.15000 0.10000 0.18000 0.04000 0.14000 0.07000
solnp--> Solution not reliable....Problem Inverting Hessian.
```

I have also encountered something like this:

```
Error in solve.default(a %*% t(a), constraint, tol = 2.220446e-16) :
Lapack routine dgesv: system is exactly singular: U[4,4] = 0
```

I hope I am explaining this problem clearly enough; any suggestions on how I might approach this would be much appreciated.

Thanks.