Numpy **matrices** are strictly 2-dimensional, while numpy **arrays** (ndarrays) are
N-dimensional. Matrix objects are a subclass of ndarray, so they inherit all
the attributes and methods of ndarrays.

The main advantage of numpy matrices is that they provide a convenient notation
for matrix multiplication: if a and b are matrices, then `a*b`

is their matrix
product.

```
import numpy as np
a = np.mat('4 3; 2 1')
b = np.mat('1 2; 3 4')
print(a)
# [[4 3]
# [2 1]]
print(b)
# [[1 2]
# [3 4]]
print(a*b)
# [[13 20]
# [ 5 8]]
```

On the other hand, as of Python 3.5, NumPy supports infix matrix multiplication using the `@`

operator, so you can achieve the same convenience of matrix multiplication with ndarrays in Python >= 3.5.

```
import numpy as np
a = np.array([[4, 3], [2, 1]])
b = np.array([[1, 2], [3, 4]])
print(a@b)
# [[13 20]
# [ 5 8]]
```

Both matrix objects and ndarrays have `.T`

to return the transpose, but matrix
objects also have `.H`

for the conjugate transpose, and `.I`

for the inverse.

In contrast, numpy arrays consistently abide by the rule that operations are
applied element-wise (except for the new `@`

operator). Thus, if `a`

and `b`

are numpy arrays, then `a*b`

is the array
formed by multiplying the components element-wise:

```
c = np.array([[4, 3], [2, 1]])
d = np.array([[1, 2], [3, 4]])
print(c*d)
# [[4 6]
# [6 4]]
```

To obtain the result of matrix multiplication, you use `np.dot`

(or `@`

in Python >= 3.5, as shown above):

```
print(np.dot(c,d))
# [[13 20]
# [ 5 8]]
```

The `**`

operator also behaves differently:

```
print(a**2)
# [[22 15]
# [10 7]]
print(c**2)
# [[16 9]
# [ 4 1]]
```

Since `a`

is a matrix, `a**2`

returns the matrix product `a*a`

.
Since `c`

is an ndarray, `c**2`

returns an ndarray with each component squared
element-wise.

There are other technical differences between matrix objects and ndarrays
(having to do with `np.ravel`

, item selection and sequence behavior).

**The main advantage of numpy arrays is that they are more general than
2-dimensional matrices**. What happens when you want a 3-dimensional array? Then
you have to use an ndarray, not a matrix object. Thus, learning to use matrix
objects is more work -- you have to learn matrix object operations, and
ndarray operations.

Writing a program that mixes both matrices and arrays makes your life difficult
because you have to keep track of what type of object your variables are, lest
multiplication return something you don't expect.

**In contrast, if you stick solely with ndarrays, then you can do everything
matrix objects can do, and more, except with slightly different
functions/notation.**

If you are willing to give up the visual appeal of NumPy matrix product
notation (which can be achieved almost as elegantly with ndarrays in Python >= 3.5), then I think NumPy arrays are definitely the way to go.

PS. Of course, you really don't have to choose one at the expense of the other,
since `np.asmatrix`

and `np.asarray`

allow you to convert one to the other (as
long as the array is 2-dimensional).

There is a synopsis of the differences between NumPy `arrays`

vs NumPy `matrix`

es here.

`A @ B`

instead of`A.dot(B)`

, where`A`

and`B`

are 2D`ndarray`

s. This removes the main advantage of using`matrix`

instead of plain`ndarray`

s, IMHO. – MiniQuark Feb 29 '16 at 19:47