The algorithm used by `leastsq`

, Levenberg-Marquardt, needs to know the value of the objective function at the current point before determining the next point. In short, there is no straightforward way to parallelize such a serial algorithm.

You can, however, parallelize your objective function in some cases. This can be done, if it's of the form:

```
def objective_f(params):
r = np.zeros([200], float)
for j in range(200):
r[j] = run_simulation(j, params)
return
def run_simulation(j, params):
r1 = ... compute j-th entry of the result ...
return r1
```

Here, you can clearly parallelize across the loop over `j`

, for instance using the multiprocessing module. Something like this: (untested)

```
def objective_f(params):
r = np.zeros([200], float)
def parameters():
for j in range(200):
yield j, params
pool = multiprocessing.Pool()
r[:] = pool.map(run_simulation, parameters())
return r
```

Another opportunity for parallelization occurs if you have to fit multiple data sets --- this is an (embarassingly) parallel problem, and the different data sets can be fitted in parallel.

If this does not help, you can look into discussion on parallelization of the LM algorithm in the literature. For instance: http://dl.acm.org/citation.cfm?id=1542338 The main optimization suggested in this paper seems to be parallelization of the numerical computation of the Jacobian. You can do this by supplying your own parallelized Jacobian function to `leastsq`

. The remaining suggestion of the paper, speculatively parallelizing Levenberg-Marquardt search steps, is however more difficult to implement and requires changes in the LM algorithm.

I'm not aware of Python (or other language) libraries implementing optimization algorithms targeted for parallel computation, although there may be some. If you manage to implement/find one of them, please advertise this on the Scipy users mailing list --- there is certainly interest in one of these!