Consider this (MATLAB R2011a):

```
a = 1e10;
>> b = inv(a)*inv(a)
b =
1.0000e-020
>> c = inv(a*a)
c =
1.0000e-020
>> b==c
ans =
0
>> format hex
>> b
b =
3bc79ca10c924224
>> c
c =
3bc79ca10c924223
```

When MATLAB calculates the intermediate quantities `inv(a)`

, or `a*a`

(whether `a`

is a scalar or a matrix), it by default stores them as the closest double precision floating point number - which is not exact. So when these slightly inaccurate intermediate results are used in subsequent calculations, there will be round off error.

Instead of comparing floating point numbers for direct equality, such as `inv(A*B*C) == inv(C)*inv(B)*inv(A)`

, it's often better to compare the absolute difference to a threshold, such as `abs(inv(A*B*C) - inv(C)*inv(B)*inv(A)) < thresh`

. Here `thresh`

can be an arbitrary small number, or some expression involving `eps`

, which gives you the smallest difference between two numbers at the precision at which you're working.

The `format`

command only controls the display of results at the command line, not the way in which results are internally stored. In particular, `format rat`

does not make MATLAB do calculations symbolically. For this, you might take a look at the Symbolic Math Toolbox. `format hex`

is often even more useful than `format long`

for diagnosing floating point precision issues such as the one you've come across.