If you are translating code in Matlab into R, then code semantics (code logic) should remain same. For example, in your code, you are transposing Q in `t(Q[,i,drop=FALSE])`

as per the given Matlab code. But `Q[,i,drop=FALSE]`

does not return the column in column vector. So, we can make it a column vector by using the statement:

```
matrix(Q[,i],n,1); # n is the number of rows.
```

There is no error in `R[j,j]=max(svd(v)$d)`

if `v`

is a vector (row or column).

Yes, there is an error in

```
v=v-R[i,j]%*%Q[,i,drop=FALSE]
```

because you are using a matrix multiplication. Instead you should use a normal multiplication:

```
v=v-R[i,j] * Q[,i,drop=FALSE]
```

Here `R[i,j]`

is a number, whereas `Q[,i,drop=FALSE]`

is a vector. So, dimension mismatch arises here.

One more thing, if `j`

is 3 , then `1:j-1`

returns [0,1,2]. So, it should be changed to `1:(j-1)`

, which returns [1,2] for the same value for `j`

. But there is a catch. If `j`

is 2, then `1:(j-1)`

returns [1,0]. So, 0th index is undefined for a vector or a matrix. So, we can bypass `0`

value by putting a conditional expression.

Here is a working code for Gram Schmidt algorithm:

```
A = matrix(c(4,3,-2,1),2,2)
m = nrow(A)
n = ncol(A)
Q = matrix(0,m,n)
R = matrix(0,n,n)
for(j in 1:n)
{
v = matrix(A[,j],n,1)
for(i in 1:(j-1))
{
if(i!=0)
{
R[i,j] = t(matrix(Q[,i],n,1))%*%matrix(A[,j],n,1)
v = v - (R[i,j] * matrix(Q[,i],n,1))
}
}
R[j,j] = svd(v)$d
Q[,j] = v/R[j,j]
}
```

If you need to wrap the code into a function, you can do so as per your convenience.

`for(i in 1:j-1)`

should be`for(i in 1:(j-1))`

and then probably you have to use brackets also here`v=v-R[i,j]%*%Q[,i,drop=FALSE]`

. – Daniel Fischer Mar 23 '13 at 7:20