# How do i design a high pass filters in MATLAB without using the builtin function?

i'm just not sure how to draw the frequency response (H) of the high pass filter? after drawing the frequency response I can get the b coefficient by taking the ifft of (H). So yeah, for a low pass filter, with a cutoff frequency of say pi/2 : the frequency response code will be `H = exp(-1*j*w*4).*(((0 <= w) & (w<= pi/2)) | ((2*pi - pi/2 <= w) & (w<=2*pi));` since the response is "1" between 0 and pi/2 and between (2*pi - pi/2) and 2*pi. Can you help me write H for a high pass filter? Thanx in advance.

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If you have a low-pass filter with frequency response `H_lp(w)`, you can find a corresponding high-pass filter `H_hp(w)` by subtracting its frequency response from 1.

``````H_hp(w) = 1 - H_lp(w)
``````

So if you want your high-pass filter to pass from `K` to `pi`, design a low-pass, which you already know how to do, that passes from `0` to `K`, then use the equation above to find the high-pass frequency response, and then take the IFFT of `H_hp`.

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Sort of. This will give you the complementary response, which may or may not be what you're after. See my answer, which involves translating the low-pass prototype up to Nyquist. –  Oliver Charlesworth Jan 2 '11 at 19:27

If you have the impulse response, `b[n]`, of a low-pass filter, you can convert it to an equivalent high-pass filter by mixing up to the Nyquist frequency. You do this by multiplying with a complex exponential: `exp(j*pi*n)`. However, this is very easy, as this is simply the sequence `+1, -1, +1, -1, ...`. Therefore, simply multiply every other sample of `b[n]` by -1.

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+1, this is by far the easier way to go. It works for IIR filters too - multiply the numerator coefficients by `+1, -1, +1, ...` and the denominator coefficients by `-1, +1, -1, ...`. –  mtrw Jan 2 '11 at 21:19