Each filter section type has particular advantages and disadvantages and each has the capability to improve particular filter parameters. The sections described below are the
prototype filters for
low-pass sections. These prototypes may be
scaled and
transformed to the desired frequency bandform (low-pass,
high-pass,
band-pass or
band-stop). The smallest unit of an image filter is an
L half-section. Because the L section is not symmetrical, it has different image impedances (\; Z_\mathsf{i} \;) on each side. These are denoted \; Z_\mathsf{iT} \; and \; Z_\mathsf{i\Pi} ~. The T and the Π in the suffix refer to the shape of the filter section that would be formed if two half sections were to be connected back-to-back. T and Π are the smallest symmetrical sections that can be constructed, as shown in diagrams in the topology chart (below). Where the section in question has an image impedance different from the general case a further suffix is added identifying the section type, for instance \; Z_{\mathsf{iT}\!\;m} ~.
Constant section The
constant or
-type filter section is the basic image filter section. It is also the simplest circuit topology. The -type has moderately fast transition from the passband to the stopband and moderately good stopband rejection. File:Lowpass Filter LC.svg|-type low-pass filter half section File:Constant k order 5.png|-type low-pass response with four (half) sections
-derived section The
-derived or
-type filter section is a development of the -type section. The most prominent feature of the -type is a pole of attenuation just past the cut-off frequency inside the stopband. The parameter adjusts the position of this pole of attenuation. Smaller values of put the pole closer to the cut-off frequency. Larger values of put it further away. In the limit, as approaches , the pole approaches of infinity and the section approaches a -type section. The -type has a particularly fast cut-off, going from fully pass at the cut-off frequency to fully stop at the pole frequency. The cut-off can be made faster by moving the pole nearer to the cut-off frequency. This filter has the fastest cut-off of any filter design; note that the fast transition is achieved with just a single section, there is no need for multiple sections. The drawback with m-type sections is that they have poor stopband rejection past the pole of attenuation. There is a particularly useful property of -type filters with =0.6 . These have maximally flat image impedance \; Z_{\mathsf{i}\!\; m} \; in the passband. They are therefore good for matching in to the filter terminations, in the passband at least, the stopband is another story. There are two variants of the -type section,
series and
shunt. They have identical transfer functions but their image impedances are different. The shunt half-section has an image impedance which matches \; Z_\mathsf{i\Pi} \; on one side but has a different impedance, \; Z_{\mathsf{iT}\!\; m} \; on the other. The series half-section matches \; Z_\mathsf{iT} \; on one side and has \; Z_{\mathsf {i\Pi}\!\; m} \; on the other. File:m-Derived Shunt Low-pass Filter Half-section.svg|-type low-pass filter shunt half section File:m-derived order 1.png|-type low-pass response single half-section =0.5 File:m-derived order 5.png|-type low-pass response with four (half) sections =0.5 File:m-Derived Series Low-pass Filter Half-section.svg|-type low-pass filter series half section File:m-type m=0.75 order 2.png|-type low-pass response single half-section =0.75 File:m-type m=0.25 order 2.png|-type low-pass response single half-section =0.25
-type section The
-type section has two independent parameters ( and ) that the designer can adjust. It is arrived at by double application of the -derivation process. Its chief advantage is that it rather better at matching in to resistive end terminations than the -type or -type. The image impedance of a half-section is \; Z_{\mathsf{i}\!\; m} \; on one side and a different impedance, \; Z_{\mathsf{i}\!\; mm'} \; on the other. Like the -type, this section can be constructed as a series or shunt section and the image impedances will come in T and Π variants. Either a series construction is applied to a shunt -type or a shunt construction is applied to a series -type. The advantages of the -type filter are achieved at the expense of greater
circuit complexity so it would normally only be used where it is needed for impedance matching purposes and not in the body of the filter. The transfer function of an -type is the same as an -type with set to the product . To choose values of and for best impedance match requires the designer to choose two frequencies at which the match is to be exact, at other frequencies there will be some deviation. There is thus some leeway in the choice, but Zobel suggests the values =0.7230 and =0.4134 which give a deviation of the impedance of less than 2% over the useful part of the band. Since =0.3, this section will also have a much faster cut-off than an -type of =0.6 which is an alternative for impedance matching. It is possible to continue the -derivation process repeatedly and produce -types and so on. However, the improvements obtained diminish at each iteration and are not usually worth the increase in complexity. File:mm'-Derived Series Low-pass Filter Half-section.svg|-type low-pass filter series half section File:m-type m=0.6 order 2.png|-type low-pass response single half-section =0.6 File:m-type m=0.3 order 2.png|-type low-pass response single half-section =0.3
Bode's filter Another variation on the -type filter was described by
Hendrik Bode. This filter uses as a prototype a mid-series m-derived filter and transforms this into a bridged-T topology with the addition of a bridging resistor. This section has the advantage of being able to place the pole of attenuation much closer to the cut-off frequency than the Zobel filter, which starts to fail to work properly with very small values of because of inductor resistance. See
equivalent impedance transforms for an explanation of its operation.
Zobel network The distinguishing feature of
Zobel network filters is that they have a constant resistance image impedance and for this reason are also known as
constant resistance networks. Clearly, the Zobel network filter does not have a problem matching to its terminations and this is its main advantage. However, other filter types have steeper transfer functions and sharper cut-offs. In filtering applications, the main role of Zobel networks is as
equalisation filters. Zobel networks are in a different group from other image filters. The constant resistance means that when used in combination with other image filter sections the same problem of matching arises as with end terminations. Zobel networks also suffer the disadvantage of using far more components than other equivalent image sections. File:Bridged-T highpass filter.svg|Zobel network bridge T high-pass filter section File:RL filter response.png|Zobel network low-pass response single section File:Zobel 5 sections.png|Zobel network low-pass response five sections
Effect of end terminations A consequence of the image method of filter design is that the effect of the end terminations has to be calculated separately if its effects on response are to be taken into account. The most severe deviation of the response from that predicted occurs in the passband close to cut-off. The reason for this is twofold. Further into the passband the impedance match progressively improves, thus limiting the error. On the other hand, waves in the stopband are reflected from the end termination due to mismatch but are attenuated twice by the filter stopband rejection as they pass through it. So while stopband impedance mismatch may be severe, it has only limited effect on the filter response. File:Theoretical T filter response.png|Theoretical -type low-pass T-filter (two half-sections) response when correctly terminated in image impedance File:T filter response, Network synthesis.png|Practical -type low-pass T-filter (two half-sections) response when terminated with fixed resistors ==Cascading sections==