Linear phase filters

In general, for $-\pi \le \le \pi$ $$H()=\left|H()\right|e^{-(i())}$$ Strictly speaking, we say $H()$ is linear phase if $$H()=\left|H()\right|e^{-(iK)}e^{-(i{}_0)}$$ Why is this important? A linear phase response gives the same time delay for ALL frequencies ! (Remember the shift theorem.) This is very desirable in many applications, particularly when theappearance of the time-domain waveform is of interest, such as in an oscilloscope. (see )

Restrictions on h(n) to get linear phase

For ${}_0=\frac{\pi }{2}$ , or $e^{-(i{}_0)}=-i$ , we require $$h(0)+h(M-1)=\text{pure imaginary}$$ $$h(0)-h(M-1)=\text{pure real number}$$ $$$$ $$h(k)=-(h^{*}(M-1-k))$$

Usually, one is interested in filters with real-valued coefficients, or see and .

So far, we have satisfied the condition that $H()=A()e^{-(i{}_0)}e^{-(i\frac{M-1}{2})}$ where $A()$ is real-valued . However, we have not assured that $A()$ is non-negative . In general, this makes the design techniques much more difficult, so mostFIR filter design methods actually design filters with Generalized Linear Phase : $H()=A()e^{-(i\frac{M-1}{2})}$ , where $A()$ is real-valued , but possible negative. $A()$ is called the amplitude of the frequency response .