Using `f`

and `x`

,

```
In [173]: f
Out[173]: array(1387)
In [174]: x
Out[174]: array([ 20404266.1330007])
```

`exponent1`

and `exponent2`

are computed and compared.

`exponent1`

is computed as follows:

```
In [183]: exponent1 = 1j * 2 * np.pi * f[..., np.newaxis, np.newaxis] * x
```

`exponent2`

is computed as follows:

```
In [186]: exponent2 = np.array([[[ 1.+0.j]]])
In [187]: exponent2 *= x[np.newaxis, ...]
In [188]: exponent2 *= f[..., np.newaxis, np.newaxis]
In [192]: exponent2 *= 1j * 2 * np.pi
```

`exponent1`

and `exponent2`

are close:

```
In [195]: np.allclose(exponent1, exponent2)
Out[195]: True
```

But their exponentials are not:

```
In [196]: np.allclose(np.exp(exponent1), np.exp(exponent2))
Out[196]: False
```

Is there a way to make their exponentials close as well? I would like the latter to be closer to the former because

```
In [198]: np.allclose(np.exp(exponent1), np.exp(1j * 2 * np.pi * 1387 * 20404266.1330007))
Out[198]: True
```