# Making a numpy ndarray matrix symmetric

I have a 70x70 numpy ndarray, which is mainly diagonal. The only off-diagonal values are the below the diagonal. I would like to make the matrix symmetric.

As a newcomer from Matlab world, I can't get it working without for loops. In MATLAB it was easy:

``````W = max(A,A')
``````

where `A'` is matrix transposition and the `max()` function takes care to make the W matrix which will be symmetric.

Is there an elegant way to do so in Python as well?

EXAMPLE The sample `A` matrix is:

``````1 0 0 0
0 2 0 0
1 0 2 0
0 1 0 3
``````

The desired output matrix `W` is:

``````1 0 1 0
0 2 0 1
1 0 2 0
0 1 0 3
``````
• is answered here Mar 6, 2015 at 17:49

Found a following solution which works for me:

``````import numpy as np
W = np.maximum( A, A.transpose() )
``````
• The problem is that if your matrix `A` is large, then this wastes a lot of space, because I suppose it creates a second matrix, or does it not? Apr 9, 2019 at 6:56
• This will not work if the off-diagonal elements you're trying to mirror are negative, no? Sep 30, 2021 at 17:41
• When dealing with negative coefficients, you would simply do `W = (A + A.transpose()) / 2` Nov 23, 2021 at 16:56

Use the NumPy `tril` and `triu` functions as follows. It essentially "mirrors" elements in the lower triangle into the upper triangle.

``````import numpy as np
A = np.array([[1, 0, 0, 0], [0, 2, 0, 0], [1, 0, 2, 0], [0, 1, 0, 3]])
W = np.tril(A) + np.triu(A.T, 1)
``````

`tril(m, k=0)` gets the lower triangle of a matrix `m` (returns a copy of the matrix `m` with all elements above the `k`th diagonal zeroed). Similarly, `triu(m, k=0)` gets the upper triangle of a matrix `m` (all elements below the `k`th diagonal zeroed).

To prevent the diagonal being added twice, one must exclude the diagonal from one of the triangles, using either `np.tril(A) + np.triu(A.T, 1)` or `np.tril(A, -1) + np.triu(A.T)`.

Also note that this behaves slightly differently to using `maximum`. All elements in the upper triangle are overwritten, regardless of whether they are the maximum or not. This means they can be any value (e.g. `nan` or `inf`).

For what it is worth, using the MATLAB's numpy equivalent you mentioned is more efficient than the link @plonser added.

``````In [1]: import numpy as np
In [2]: A = np.zeros((4, 4))
In [3]: np.fill_diagonal(A, np.arange(4)+1)
In [4]: A[2:,:2] = np.eye(2)

# numpy equivalent to MATLAB:
In [5]: %timeit W = np.maximum( A, A.T)
100000 loops, best of 3: 2.95 µs per loop

In [6]: %timeit W = A + A.T - np.diag(A.diagonal())
100000 loops, best of 3: 9.88 µs per loop
``````

Timing for larger matrices can be done similarly:

``````In [1]: import numpy as np
In [2]: N = 100
In [3]: A = np.zeros((N, N))
In [4]: A[2:,:N-2] = np.eye(N-2)
In [5]: np.fill_diagonal(A, np.arange(N)+1)
In [6]: print A
Out[6]:
array([[   1.,    0.,    0., ...,    0.,    0.,    0.],
[   0.,    2.,    0., ...,    0.,    0.,    0.],
[   1.,    0.,    3., ...,    0.,    0.,    0.],
...,
[   0.,    0.,    0., ...,   98.,    0.,    0.],
[   0.,    0.,    0., ...,    0.,   99.,    0.],
[   0.,    0.,    0., ...,    1.,    0.,  100.]])

# numpy equivalent to MATLAB:
In [6]: %timeit W = np.maximum( A, A.T)
10000 loops, best of 3: 28.6 µs per loop

In [7]: %timeit W = A + A.T - np.diag(A.diagonal())
10000 loops, best of 3: 49.8 µs per loop
``````

And with N = 1000

``````# numpy equivalent to MATLAB:
In [6]: %timeit W = np.maximum( A, A.T)
100 loops, best of 3: 5.65 ms per loop

In [7]: %timeit W = A + A.T - np.diag(A.diagonal())
100 loops, best of 3: 11.7 ms per loop
``````
• It's roughly 3x times. Does it hold for larger matrices, say 100x100 or 1000x1000? Mar 6, 2015 at 22:14
• @xeon I added timings for the sizes you mentioned. These timings are on my machine, YMMV. The difference of ~2x comes from the number of operations performed. Both use numpy objects and numpy methods. Similar to MATLAB, numpy was designed to optimize matrix operations so numpy methods are typically the most efficient. Mar 6, 2015 at 22:34
• I swapped `A.transpose()` for `A.T` to point out they are the same and one requires less typing (docs.scipy.org/doc/numpy/reference/generated/…). Mar 6, 2015 at 22:37

can get symmetric positive-definite

``````import pandas as pd
from sklearn.datasets import make_spd_matrix    # spd - symmetric positive-definite matrix

spd = make_spd_matrix(n_dim=3, random_state=1)
print(pd.DataFrame(spd))
``````

All solutions so far use a floating point operation (for every matrix element), either `+` or `max`, where you don’t actually need one.

You could just use indexing to copy the transposed bit of the matrix:

``````idx = np.triu_indices(A.shape[0], 1, A.shape[1])
A[idx] = A.T[idx]
``````

However indexing is a bit slow, so for an alternate (and shorter) way of doing the same, you could use `np.where` and generate which values to pick with `np.tri`:

``````np.where(np.tri(*A.shape, dtype=bool), A, A.T)
``````

Did some benchmarking on a random `1000 x 1000` matrix:

Code run with `timeit.timeit('…', globals={'np': np, 'A': A}, number=1000)` time
`np.maximum(A, A.T)` * 5.29
`A + np.triu(A.T, 1)` 2.61
`A + A.T - np.diag(A.diagonal())` 5.71
`np.tril(A, -1) + A.T` 2.45
`idx = np.triu_indices(A.shape[0], 1, A.shape[1]) ; A[idx] = A.T[idx]` 21.82
`np.where(np.tri(*A.shape, dtype=bool), A, A.T)` 2.00

* as noted above this version only works for positive numbers only.