*(This answer "addreses" the problem when direct np.reshape() doesn't organize the final array as we want it. If we want to directly reshape into 3D np.reshape will do it, but watch out for the final organization of the input).*

In my personal try to finally **resolve this problem of feeding input shape for RNN** and not confuse anymore, I will give my "personal" explanation for this.

In my case (and I think that many others may have this organization scheme in their feature matrices), most of the blogs outside "don't help". Let's give it a try in how to convert a 2D feature matrix into a 3D shaped one for RNNs.

Let's say we have this **organization type in our feature matrix**: we have **5 observations** (i.e. rows - for convention I think it is the most logical term to use) and in each row, we have **2 features for EACH timestep (and we have 2 timesteps)**, like this:

(The `df`

is to better understand visually my words)

```
In [1]: import numpy as np
In [2]: arr = np.random.randint(0,10,20).reshape((5,4))
In [3]: arr
Out[3]:
array([[3, 7, 4, 4],
[7, 0, 6, 0],
[2, 0, 2, 4],
[3, 9, 3, 4],
[1, 2, 3, 0]])
In [4]: import pandas as pd
In [5]: df = pd.DataFrame(arr, columns=['f1_t1', 'f2_t1', 'f1_t2', 'f2_t2'])
In [6]: df
Out[6]:
f1_t1 f2_t1 f1_t2 f2_t2
0 3 7 4 4
1 7 0 6 0
2 2 0 2 4
3 3 9 3 4
4 1 2 3 0
```

We will now take the values to work with them. The thing here is that **RNNs incorporate the "timestep" dimension to their input**, because of their architechtural nature. We can imagine that dimension as **stacking 2D arrays one behind the other for the number of timesteps we have.** In this case, we have two timesteps; so we will have two 2D arrays stacked: one for timestep1 and behind that, the one for timestep2.

In reality, in that 3D input we need to make, we still have 5 observations. The thing is that we need to arrange them differently: the RNN will take the first row (or specified batch - but we will keep it simple here) of the first array (i.e. timestep1) and the first row of the second stacked array (i.e. timestep2). Then the second row...until the last one (the 5th one in our example). S*o, in each row of each timestep, we need to have the two features, of course, separated in different arrays each one corresponding to its timestep*. Let's see this with the numbers.

I will make two arrays for easier understanding. Remember that, because of our organizational scheme in the df, you might have noticed that **we need to take the first two columns (i.e. features 1 and 2 for the timestep1) as our FIRST ARRAY OF THE STACK and the last two columns, that is, the 3rd and the 4th, as our SECOND ARRAY OF THE STACK**, so that everything makes sense finally.

```
In [7]: arrStack1 = arr[:,0:2]
In [8]: arrStack1
Out[8]:
array([[3, 7],
[7, 0],
[2, 0],
[3, 9],
[1, 2]])
In [9]: arrStack2 = arr[:,2:4]
In [10]: arrStack2
Out[10]:
array([[4, 4],
[6, 0],
[2, 4],
[3, 4],
[3, 0]])
```

Finally, the only thing we need to do is stack both arrays ("one behind the other") as if they were part of the same final structure:

```
In [11]: arrfinal3D = np.stack([arrStack1, arrStack2])
In [12]: arrfinal3D
Out[12]:
array([[[3, 7],
[7, 0],
[2, 0],
[3, 9],
[1, 2]],
[[4, 4],
[6, 0],
[2, 4],
[3, 4],
[3, 0]]])
In [13]: arrfinal3D.shape
Out[13]: (2, 5, 2)
```

That's it: we have our feature matrix ready to be fed into the RNN cell, taking into account our organization of the 2D feature matrix.

(For a one liner regarding all this you could use:

```
In [14]: arrfinal3D_1 = np.stack([arr[:,0:2], arr[:,2:4]])
In [15]: arrfinal3D_1
Out[15]:
array([[[3, 7],
[7, 0],
[2, 0],
[3, 9],
[1, 2]],
[[4, 4],
[6, 0],
[2, 4],
[3, 4],
[3, 0]]])
```