The task is to combine two arrays row by row (construct the permutations) based on the resulting multiplication of two corresponding vectors. Such as:

Row1_A, Row2_A, Row3_A,

Row1_B, Row2_B, Row3_B,

The result should be: Row1_A_Row1_B, Row1_A_Row2_B, Row1_A_Row3_B, Row2_A_Row1_B, etc..

Given the following initial arrays:

```
n_rows = 1000
A = np.random.randint(10, size=(n_rows, 5))
B = np.random.randint(10, size=(n_rows, 5))
P_A = np.random.rand(n_rows, 1)
P_B = np.random.rand(n_rows, 1)
```

Arrays P_A and P_B are corresponding vectors to the individual arrays, which contain a float. The combined rows should only appear in the final array if the multiplication surpasses a certain threshold, for example:

```
lim = 0.8
```

I have thought of the following functions or ways to solve this problem, but I would be interested in faster solutions. I am open to using numba or other libraries, but ideally I would like to improve the vectorized solution using numpy.

Method A

```
def concatenate_per_row(A, B):
m1,n1 = A.shape
m2,n2 = B.shape
out = np.zeros((m1,m2,n1+n2),dtype=A.dtype)
out[:,:,:n1] = A[:,None,:]
out[:,:,n1:] = B
return out.reshape(m1*m2,-1)
%%timeit
A_B = concatenate_per_row(A, B)
P_A_B = (P_A[:, None]*P_B[None, :])
P_A_B = P_A_B.flatten()
idx = P_A_B > lim
A_B = A_B[idx, :]
P_A_B = P_A_B[idx]
```

37.8 ms ± 660 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)

Method B

```
%%timeit
A_B = []
P_A_B = []
for i in range(len(P_A)):
P_A_B_i = P_A[i]*P_B
idx = np.where(P_A_B_i > lim)[0]
if len(idx) > 0:
P_A_B.append(P_A_B_i[idx])
A_B_i = np.zeros((len(idx), A.shape[1] + B.shape[1]), dtype='int')
A_B_i[:, :A.shape[1]] = A[i]
A_B_i[:, A.shape[1]:] = B[idx, :]
A_B.append(A_B_i)
A_B = np.concatenate(A_B)
P_A_B = np.concatenate(P_A_B)
```

9.65 ms ± 291 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)