We could use the formula of `standard deviation`

and `mean`

to compute those two scalar values for all input arrays without concatenating/stacking (that could be costly specially on large NumPy arrays). Let's do it in steps - mean and then standard deviation, as it seems we could use `mean`

in `std`

computations.

**Getting the combined mean value :**

So, we will start with the mean/averaging. For this, we would get the summation scalar for each array. Then, get the total summation and finally divide by the number of elements in all arrays.

**Getting the combined standard deviation value :**

For standard deviation, we have the formula as :

So, we will use the combined mean value obtained from previous step, use the `std`

formula to get the squared differentiation, divide by the total number of elements across all arrays and then apply square root.

**Implementation**

Let's say the input arrays are `a`

and `b`

, we would have one solution, like so -

```
N = float(a.size + b.size)
mean_ = (a.sum() + b.sum())/N
std_ = np.sqrt((((a - mean_)**2).sum() + ((b - mean_)**2).sum())/N)
```

**Sample run for verification**

```
In [266]: a = np.random.rand(3,4,2)
...: b = np.random.rand(2,5,3)
...:
In [267]: N = float(a.size + b.size)
...: mean_ = (a.sum() + b.sum())/N
...: std_ = np.sqrt((((a - mean_)**2).sum() + ((b - mean_)**2).sum())/N)
...:
In [268]: mean_
Out[268]: 0.47854757879348042
In [270]: std_
Out[270]: 0.27890341338373376
```

Now, to verify, let's stack and then use relevant ufuncs -

```
In [271]: A = np.hstack((a.ravel(), b.ravel()))
In [273]: A.mean()
Out[273]: 0.47854757879348037
In [274]: A.std()
Out[274]: 0.27890341338373376
```

**List of arrays as input**

For a list holding all those arrays, we need to iterate through them, like so -

```
A = [a,b,c] # input list of arrays
N = float(sum([i.size for i in A]))
mean_ = sum([i.sum() for i in A])/N
std_ = np.sqrt(sum([((i-mean_)**2).sum() for i in A])/N)
```

Sample run -

```
In [301]: a = np.random.rand(3,4,2)
...: b = np.random.rand(2,5,3)
...: c = np.random.rand(7,4)
...:
In [302]: A = [a,b,c] # input list of arrays
...: N = float(sum([i.size for i in A]))
...: mean_ = sum([i.sum() for i in A])/N
...: std_ = np.sqrt(sum([((i-mean_)**2).sum() for i in A])/N)
...: print mean_, std_
...:
0.47703535428 0.293308550786
In [303]: A = np.hstack((a.ravel(), b.ravel(), c.ravel()))
...: print A.mean(), A.std()
...:
0.47703535428 0.293308550786
```