I saw this example in the SciPy documentation:
x, y = np.random.multivariate_normal(mean, cov, 5000).T
What does the final .T actually do here?
The .T
accesses the attribute T
of the object, which happens to be a NumPy array. The T
attribute is the transpose of the array, see the documentation.
Apparently you are creating random coordinates in the plane. The output of multivariate_normal()
might look like this:
>>> np.random.multivariate_normal([0, 0], [[1, 0], [0, 1]], 5)
array([[ 0.59589335, 0.97741328],
[-0.58597307, 0.56733234],
[-0.69164572, 0.17840394],
[-0.24992978, -2.57494471],
[ 0.38896689, 0.82221377]])
The transpose of this matrix is:
array([[ 0.59589335, -0.58597307, -0.69164572, -0.24992978, 0.38896689],
[ 0.97741328, 0.56733234, 0.17840394, -2.57494471, 0.82221377]])
which can be conveniently separated in x
and y
parts by sequence unpacking.
T
is a descriptor. You can think of it as basically a function that is called whenever you access .T
. Also note that the transpose is just a view into the same data as the original array, just with different strides. So if you do b = a.T
and then change items in a
, the corresponding items in b
will also change.
Oct 14, 2021 at 21:20
.T is just np.transpose(). Best of luck
Example
import numpy as np
a = [[1, 2, 3]]
b = np.array(a).T # ndarray.T The transposed array. [[1,2,3]] -> [[1][2][3]]
print("a=", a, "\nb=", b)
for i in range(3):
print(" a=", a[0][i]) # prints 1 2 3
for i in range(3):
print(" b=", b[i][0]) # prints 1 2 3
.T
reverses the order of the axes, instead of switching the last two. This means if your arrayx
is 3-D,x.T
is the same asx.transpose((2, 1, 0))
. If you want to switch the last two axes, in this case, you would dox.transpose((0, 2, 1))
.