One would expect and hope that if you ask `Mathematica`

to find the roots of a polynomial, it should give the same (approximate) answers whether you do this symbolically, then find numerical approximations to these exact answers, or whether you do it numerically. Here's an example which (in `Mathematica 7`

, running on OS X) where this fails badly:

```
poly = -112 + 1/q^28 + 1/q^26 - 1/q^24 - 6/q^22 - 14/q^20 - 25/q^18 -
38/q^16 - 52/q^14 - 67/q^12 - 81/q^10 - 93/q^8 - 102/q^6 - 108/
q^4 - 111/q^2 - 111 q^2 - 108 q^4 - 102 q^6 - 93 q^8 - 81 q^10 -
67 q^12 - 52 q^14 - 38 q^16 - 25 q^18 - 14 q^20 - 6 q^22 - q^24 +
q^26 + q^28;
Total[q^4 /. NSolve[poly == 0, q]] - Total[q^4 /. N[Solve[poly == 0, q]]]
```

(Note: this is actually a Laurent polynomial, and if you multiply through by a large power of `q`

the problem goes away.)

The last line here is just a demonstration that the solutions found are very different; in fact it's the quantity we were trying to compute in the problem we were working on.

If you look closely at the output of `NSolve[poly == 0, q]`

and of `N[Solve[poly == 0, q]`

, you'll see that NSolve only gives `54`

roots instead of the expected `56`

. It's not that it just missed a repeated root or anything; it's missing the two largest roots in magnitude (approximately `+/- 1.59`

)

Is this a bug in Mathematica? Does anyone have an explanation for why this is happening?