If Z and Y are the series impedance and shunt admittance of a constant k half section and;

${\displaystyle Z=Z_{1}+Z_{2}+Z_{3}+\dots +Z_{N}}$ 

where Z₁, Z₂ etc are a cascade of antiresonators,

the transformed series impedance for a mid-series derived filter becomes;

${\displaystyle Z_{m_{n}}=m_{1}Z_{1}+m_{2}Z_{2}+m_{3}Z_{3}+\dots +m_{N}Z_{N}}$ 

Where the m_n are arbitrary positive coefficients. For an invariant image impedance Z_iT and invariant bandform (that is, invariant cut-off frequencies ω_c) the transformed shunt admittance, expressed in terms of Z_mn, is given by;

${\displaystyle Y_{m_{n}}={\frac {Z_{m_{n}}}{k^{2}+Z^{2}-Z_{m_{n}}^{2}}}}$ 

where ${\displaystyle k={\sqrt {\frac {Z}{Y}}}}$  and is a constant by definition. When the m_n are all equal this reduces to the expression for an m-type filter and where they are all equal to one it reduces further to the k-type filter.

A result of this relationship is that the N antiresonators in Z_mn will transform into 2N resonators in Y_mn. The coefficients m_n can be adjusted by the designer to set the frequency of one of the two poles of attenuation, ω_∞, in each stopband. The second pole of attenuation is dependent and cannot be set separately.

Special cases edit

In the case of a filter with a stopband extending to zero frequency, one of the antiresonators in Z will reduce to a single inductor. In this case, the resonators in Y_mn are reduced by one to 2N-1. Similarly, for a filter with a stopband extending to infinity, one antiresonator will reduce to a single capacitor and the resonators will again be reduced by one. In a filter where both conditions pertain, the number of resonators will be 2N-2. For these end stopbands, there is only one pole of attenuation in each, as would be expected from the reduced number of resonators. These forms are the maximum allowable complexity while maintaining invariance of bandform and one image impedance.

By dual analogy, the shunt-derived filter starts from;

${\displaystyle Y_{m_{n}}=m_{1}Y_{1}+m_{2}Y_{2}+m_{3}Y_{3}+\dots +m_{N}Y_{N}}$ 

For an invariant image admittance Y_iΠ and invariant bandform the transformed series impedance is given by;

${\displaystyle Z_{m_{n}}={\frac {Y_{m_{n}}}{k^{2}+Y^{2}-Y_{m_{n}}^{2}}}}$ 

The bandpass filter can be characterised as a 2-bandstop filter with ω_c = 0 for the lower critical frequency of the lower band and ω_c = ∞ for the upper critical frequency of the upper band. The two resonators reduce to an inductor and a capacitor, respectively. The number of antiresonators reduces to two.

If, however, ω_∞1 is set to zero (that is, there is no pole of attenuation in the lower stopband) and ω_∞2 is set to correspond to the upper critical frequency ω'_c1, then a particularly simple form of the bandpass filter is obtained consisting of just antiresonators coupled by capacitors. This was a popular topology for multi-section band-pass filters due to its low component count, particularly of inductors.^[2][3] Many other such reduced forms are possible by setting one of the poles of attenuation to correspond to one of the critical frequencies for various classes of the basic filter.^[4]

• Image impedance
• Constant k filter
• m-derived filter
• mm'-type filter
• Composite image filter

• Zobel, O. J.,Theory and Design of Uniform and Composite Electric Wave Filters, Bell System Technical Journal, Vol. 2 (1923), pp. 1-46.
• Mathaei, Young, Jones Microwave Filters, Impedance-Matching Networks, and Coupling Structures McGraw-Hill 1964.
• Bray, J, Innovation and the Communications Revolution, Institution of Electrical Engineers, 2002 ISBN 0-85296-218-5