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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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2 Answers 2

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

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