The real FFT in numpy uses the fact that the fourier transform of a real valued function is so to say "skew-symmetric", that is the value at frequency `k`

is the complex conjugate of the value at frequency `N-k`

for `k=1..N-1`

(the correct term is *Hermitian*). Therefore `rfft`

returns only the part of the result that corresponds to nonpositive frequences.

For an input of size `N`

the `rfft`

function returns the part of the FFT output corresponding to frequences at or below `N/2`

. Therefore the output of `rfft`

is of size `N/2+1`

if `N`

is even (all frequences from `0`

to `N/2`

), or `(N+1)/2`

if `N`

is odd (all frequences from 0 to `(N-1)/2`

). Observe that the function `floor(n/2+1)`

returns the correct output size for both even and odd input sizes.

So to reproduce `rfft`

in matlab

```
function rfft = rfft(a)
ffta = fft(a);
rfft = ffta(1:(floor(length(ffta)/2)+1));
end
```

For example

```
a = [1,1,1,1,-1,-1,-1,-1];
rffta = rfft(a)
```

would produce

```
rffta =
Columns 1 through 3:
0.00000 + 0.00000i 2.00000 - 4.82843i 0.00000 + 0.00000i
Columns 4 through 5:
2.00000 - 0.82843i 0.00000 + 0.00000i
```

Now compare that with python

```
>>> np.fft.rfft(a)
array([ 0.+0.j , 2.-4.82842712j, 0.-0.j ,
2.-0.82842712j, 0.+0.j ])
```

### Reproducing irfft

To reproduce basic functionality of `irfft`

you need to recover the missing frequences from `rfft`

output. If the desired output length is even, the output length can be computed from the input length as `2 (m - 1)`

. Otherwise it should be `2 (m - 1) + 1`

.

The following code would work.

```
function irfft = irfft(x,even=true)
n = 0; % the output length
s = 0; % the variable that will hold the index of the highest
% frequency below N/2, s = floor((n+1)/2)
if (even)
n = 2 * (length(x) - 1 );
s = length(x) - 1;
else
n = 2 * (length(x) - 1 )+1;
s = length(x);
endif
xn = zeros(1,n);
xn(1:length(x)) = x;
xn(length(x)+1:n) = conj(x(s:-1:2));
irfft = ifft(xn);
end
```

Now you should have

```
>> irfft(rfft(a))
ans =
1.00000 1.00000 1.00000 1.00000 -1.00000 -1.00000 -1.00000 -1.00000
```

and also

```
abs( irfft(rfft(a)) - a ) < 1e-15
```

For odd output length you get

```
>> irfft(rfft(a(1:7)),even=false)
ans =
1.0000 1.0000 1.0000 1.0000 -1.0000 -1.0000 -1.0000
```