`np.max`

is just an alias for `np.amax`

. This function only works on a *single* input array and finds the value of maximum element in that entire array (returning a scalar). Alternatively, it takes an `axis`

argument and will find the maximum value along an axis of the input array (returning a new array).

```
>>> a = np.array([[0, 1, 6],
[2, 4, 1]])
>>> np.max(a)
6
>>> np.max(a, axis=0) # max of each column
array([2, 4, 6])
```

The default behaviour of `np.maximum`

is to take *two* arrays and compute their element-wise maximum. Here, 'compatible' means that one array can be broadcast to the other. For example:

```
>>> b = np.array([3, 6, 1])
>>> c = np.array([4, 2, 9])
>>> np.maximum(b, c)
array([4, 6, 9])
```

But `np.maximum`

is also a universal function which means that it has other features and methods which come in useful when working with multidimensional arrays. For example you can compute the cumulative maximum over an array (or a particular axis of the array):

```
>>> d = np.array([2, 0, 3, -4, -2, 7, 9])
>>> np.maximum.accumulate(d)
array([2, 2, 3, 3, 3, 7, 9])
```

This is not possible with `np.max`

.

You can make `np.maximum`

imitate `np.max`

to a certain extent when using `np.maximum.reduce`

:

```
>>> np.maximum.reduce(d)
9
>>> np.max(d)
9
```

Basic testing suggests the two approaches are comparable in performance; and they should be, as `np.max()`

actually calls `np.maximum.reduce`

to do the computation.