[edited:] I cannot tell whaht your original definition of operator `phi`

is, as there is a syntax error in the original post (invalid syntax). In particular I cannot tell whether you meant,

```
phi := z -> (l*z+a)/(1-l*conjugate(a)*z):
```

or,

```
phi := z -> z (l*z+a)/(1-l*conjugate(a)*z):
```

I used the former below. The results will depend upon the choice, of course.

In a previous question by you an answer involved using `evalc`

, under which all unknowns would be treated as real.

But now you seem to have a mix, where `l`

is to be taken as real while `a`

may be complex.

As shown in your earlier question another approach is to use assumptions on the unknowns, which in this case can give finer control over your mix.

Note that `a`

will get treated as being possibly complex, by default. So we can use an assumption on just `l`

.

```
restart:
omega := z -> 2*<Re(z), Im(z), 1>/(1+abs(z)^2):
phi := z -> (l*z+a)/(1-l*conjugate(a)*z):
expr := omega(phi(1/e)):
map(limit,expr,e=0) assuming l::real:
map(simplify,%);
[ 2 Re(a) ]
[- ----------]
[ 2 ]
[ | a | + 1]
[ ]
[ 2 Im(a) ]
[- ----------]
[ 2 ]
[ | a | + 1]
[ ]
[ 2 ]
[ 2 | a | ]
[ ---------- ]
[ 2 ]
[ | a | + 1 ]
```

Here is another way to get a result. We could let `a=S+T*I`

and use `evalc`

to handle altogether the assumptions that `S`

and `T`

(and `l`

) are purely real.

```
map(limit,subs(a=S+T*I,expr),e=0) assuming l::real:
simplify(map(evalc,%));
[ 2 S ]
[- -----------]
[ 2 2 ]
[ S + T + 1]
[ ]
[ 2 T ]
[- -----------]
[ 2 2 ]
[ S + T + 1]
[ ]
[ 2 2 ]
[ 2 (S + T ) ]
[ ----------- ]
[ 2 2 ]
[ S + T + 1 ]
```

`limit`

command in your assignment to`H`

. You'd need to do that, just as for`Omega`

, since`expr2`

is a Vector just as is`expr`

. – acer May 6 '14 at 17:22