I do not quite understand why `numpy.linalg.solve()`

gives the more precise answer, whereas `numpy.linalg.inv()`

breaks down somewhat, giving (what I believe are) estimates.

For a concrete example, I am solving the equation `C^{-1} * d`

where `C`

denotes a matrix, and `d`

is a vector-array. For the sake of discussion, the dimensions of `C`

are shape `(1000,1000)`

and `d`

is shape `(1,1000)`

.

`numpy.linalg.solve(A, b)`

solves the equation `A*x=b`

for x, i.e. `x = A^{-1} * b.`

Therefore, I could either solve this equation by

(1)

```
inverse = numpy.linalg.inv(C)
result = inverse * d
```

or (2)

```
numpy.linalg.solve(C, d)
```

Method (2) gives far more precise results. Why is this?

What exactly is happening such that one "works better" than the other?

neverwant to compute the inverse of a matrix... it's inefficient, and the error is generally higher than other methods. – Bakuriu Oct 3 '16 at 7:14