You can set all the values of `xdft`

to zero except those you want, i.e.,

```
xdft = fft(x);
xdft = xdft(1:ceil(length(xdft) / 2));
xdft(1:a) = 0;
xdft(b+1:end) = 0;
ixdft = ifft(xdft, 'symmetric');
```

The reason I have taken only half of the original FFT'd data is that your result will be symmetric about Fs / 2 (where Fs is the sample rate), and if you don't do the same thing to the frequencies either side of the centre, you will get a complex signal out. Instead of doing the same thing to both sides manually, I've just taken one side, modified it, and told `ifft`

that it has to reconstruct the data for the full frequency range by appending a mirror image of what you pass it; this by done by calling it with the `'symmetric'`

option.

If you need to figure out what `a`

and `b`

should be for some frequency, you can first create a vector of the frequencies at which you've performed the FFT, then find those frequencies that are within your range, like so:

```
xdft = fft(x);
xdft = xdft(1:ceil(length(xdft) / 2));
f = linspace(0, Fs / 2, length(xdft));
keepInd = f >= 8 & f <= 12; % Keep frequencies between 8 and 12 Hz
xdft(~keepInd) = 0;
```

Note that I've actually omitted the use of the two variables `a`

and `b`

altogether in this example and opted for logical indexing, and that `Fs`

is the sample rate.