Since the poles come first in the DF-II realization of an IIR filter,
the signal entering the state delay-line (see Fig.9.2) typically
requires a larger dynamic range than the output signal . In
other words, it is common for the feedback portion of a DF-II IIR
filter to provide a large signal boost which is then
compensated by attenuation in the feedforward portion (the
zeros). As a result, if the input dynamic range is to remain
unrestricted, the two delay elements may need to be implemented with
high-order guard bits to accommodate an extended dynamic range.
If the number of bits in the delay elements is doubled (which still
does not guarantee impossibility of internal overflow), the benefit of
halving the number of delays relative to the DF-I structure may be
largely canceled. In other words, the DF-II structure, which is
canonical with respect to delay, may require just as much or more
memory as the DF-I structure, even though the DF-I uses twice as many
addressable delay elements for the filter state memory.
. In
other words, it is common for the feedback portion of a DF-II IIR
filter to provide a large signal boost which is then
compensated by attenuation in the feedforward portion (the
zeros). As a result, if the input dynamic range is to remain
unrestricted, the two delay elements may need to be implemented with
high-order guard bits to accommodate an extended dynamic range.
If the number of bits in the delay elements is doubled (which still
does not guarantee impossibility of internal overflow), the benefit of
halving the number of delays relative to the DF-I structure may be
largely canceled. In other words, the DF-II structure, which is
canonical with respect to delay, may require just as much or more
memory as the DF-I structure, even though the DF-I uses twice as many
addressable delay elements for the filter state memory.
