It depends on the accuracy required. Since 1e100 cannot be exactly represented by a double, you have a problem.

This works, if you are willing to accept that it does not yield an exact solution. But then, I just said that 1e100 is not represented exactly as a double anyway. Thus, in MATLAB,

```
exp(log(1e100)/4)
ans =
1e+25
```

Ok, so it looks like 1e25 is the answer, but is it really? In fact, the number we really get, in terms of a double, is: 10000000000000026675773440.

One problem is the original number was not represented exactly anyway. So 1e100, when stored in the IEEE format, is more accurately stored as something like this:

```
1.00000000000000001590289110975991804683608085639452813897813e100
```

To solve this exactly, you would best be served by a big integer form, but a big decimal form would do reasonably well too.

Thus, in MATLAB, using my big decimal (HPF) form we see that 1e100 is exactly represented in 100 digits of precision.

```
x = hpf('1e100',100)
x =
1.e100
```

And, to 100 digits of precision, the root is correct.

```
exp(log(x)/4)
ans =
10000000000000000000000000
```

Actually though, be careful, as any floating point form cannot represent real numbers exactly. To more precision, we see that the number computed was actually slightly in error:

9999999999999999999999999.9999999999999999999999999999999999999999999999999999999999999999999999999999999999800

A big integer form will yield an exact result, if one exists. Thus, using a big integer form, we see the expected result:

```
vpi(10)^100
ans =
10000000000000000000000000000000000000000000000000000000000000000000
000000000000000000000000000000000
nthroot(vpi(10)^100,4)
ans =
10000000000000000000000000
```

The point is, to do the computation you desire, you need to use tools that can do the computation. There are many such big decimal or big integer tools to be had. For example, Java has a BigDecimal and a BigInteger form that I have used on occasion (though I've written my own tools anyway, thus in MATLAB, HPF and VPI.)