Filters Filter, filtering or filters may refer to: Science and technology Computing * Filter (higher-order function), in functional programming * Filter (software), a computer program to process a data stream * Filter (video), a software component th ...

designed using the

image impedance Image impedance is a concept used in electronic network design and analysis and most especially in filter design. The term ''image impedance'' applies to the impedance seen looking into a port of a network. Usually a two-port network is implied but ...

methodology suffer from a peculiar flaw in the theory. The predicted characteristics of the filter are calculated assuming that the filter is terminated with its own image impedances at each end. This will not usually be the case; the filter will be terminated with fixed resistances. This causes the filter response to deviate from the theoretical. This article explains how the effects of image filter end terminations can be taken into account. Generally, the effect of the terminations is to cause a rounding of the frequency response at cut-off. The image method predicts a sharp discontinuity in the slope of the response at cut-off which is not realised in practice, although a well designed

image filter An image is a visual representation of something. It can be two-dimensional, three-dimensional, or somehow otherwise feed into the visual system to convey information. An image can be an artifact, such as a photograph or other two-dimensiona ...

may get close to this. Another prediction of the image method is zero loss in the

passband A passband is the range of frequencies or wavelengths that can pass through a filter. For example, a radio receiver contains a bandpass filter to select the frequency of the desired radio signal out of all the radio waves picked up by its anten ...

(assuming ideal lossless components). Again, this cannot be achieved in practice because reflections from the end terminations always cause some loss. __TOC__

Symbols used in this article

Impedances

Z_\,\!

the

at end 1 *

Z_\,\!

the image impedance at end 2 *

Z_I\,\!

the image impedance when both ends are identical *

R_1\,\!

the terminating resistance at end 1 *

R_2\,\!

the terminating resistance at end 2 *

R\,\!

the terminating resistance when both ends are identical

Coefficients

r_\,\!

the

reflection coefficient In physics and electrical engineering the reflection coefficient is a parameter that describes how much of a wave is reflected by an impedance discontinuity in the transmission medium. It is equal to the ratio of the amplitude of the reflected w ...

at end 1 *

r_\,\!

the reflection coefficient at end 2 *

r_\,\!

the reflection coefficient when both ends are identical *

\tau_\,\!

the

transmission coefficient The transmission coefficient is used in physics and electrical engineering when wave propagation in a medium containing discontinuities is considered. A transmission coefficient describes the amplitude, intensity, or total power of a transmit ...

at end 1 *

\tau_\,\!

the transmission coefficient at end 2 *

\gamma\,\!

the complex propagation coefficient of the filter *

\alpha\,\!

the

attenuation coefficient The linear attenuation coefficient, attenuation coefficient, or narrow-beam attenuation coefficient characterizes how easily a volume of material can be penetrated by a beam of light, sound, particles, or other energy or matter. A coefficient valu ...

of the filter *

\beta\,\!

the

phase coefficient The propagation constant of a sinusoidal electromagnetic wave is a measure of the change undergone by the amplitude and phase of the wave as it propagates in a given direction. The quantity being measured can be the voltage, the current in a circ ...

of the filter Note that all of these coefficients are defined relative to the image impedance and not the actual input impedance of the filter.

General case

The transfer function of any filter connected as shown in the diagram above is given by the expression :

A(i\omega)=\frac=\sqrte^\left \frac \right /math>

where

: r_=\frac : r_=\frac : \tau_=\frac : \tau_=\frac Note that ''V

_i'' is the nominal voltage that would be delivered by the generator if it were terminated in its characteristic impedance (i.e. ''R₁''), not the actual voltage appearing at the input terminals of the filter. It can further be noted that the first part of the expression, :

\sqrte^

, is the same as the expression for the transfer function without taking into account the end terminations. The second part of the expression is thus that part of the response caused by the mismatched impedances; :

\left \frac \right

Symmetrical case

Where the filter has

symmetrical Symmetry (from grc, συμμετρία "agreement in dimensions, due proportion, arrangement") in everyday language refers to a sense of harmonious and beautiful proportion and balance. In mathematics, "symmetry" has a more precise definit ...

image impedances and terminations, the expression can be considerably reduced. Note that there is no requirement for the filter to be symmetrical internally, only that the end sections have the same image impedance facing into identical terminating impedances. :

A(i\omega)=e^\left \frac \right /math>

A further simplification can be made if there are no resistive losses in the filter (or they are assumed to be negligible).   In this case, the image impedance is purely real (''R

_I'') in the passband and purely imaginary (''iX_I'') in the stopband. The magnitude of the transfer function is given by :

\left, A\=\frac

where for the passband, :

\xi=\frac\left(\frac-\frac\right)\sin\beta

and for the stopband, :

\xi=\frac\left(\frac-\frac\right)\sinh\beta.

Antimetrical case

A similar simplification can be made for lossless antimetrical filters. In this case the substitution :

Z_Z_=R_1R_2=R_o^2

is made into the general equation. For the passband,

\xi=\frac\left(\frac-\frac\right)\cos\beta.

and for the stopband,

\xi=\frac\left(\frac-\frac\right)\sinh\beta.

Antimetrical, in this context, means that the filter image impedances and terminations at each end are the

dual Dual or Duals may refer to: Paired/two things * Dual (mathematics), a notion of paired concepts that mirror one another ** Dual (category theory), a formalization of mathematical duality *** see more cases in :Duality theories * Dual (grammatical ...

of each other. This will be the case if the filter has a series and shunt section of the same type, respectively, at each end. Symmetrical filters have an even number of half-sections and antimetrical filters have an odd number of half-sections. In the vast majority of cases the filter design will be either symmetrical or antimetrical and one of these reduced expressions will apply.

Some example response plots

References

{{reflist :* Matthaei, Young, Jones ''Microwave Filters, Impedance-Matching Networks, and Coupling Structures'', pp68-72, McGraw-Hill 1964. Linear filters Image impedance filters Filter theory Analog circuits Electronic design

Symbols used in this article

Impedances

Coefficients

General case

Symmetrical case

Antimetrical case

Some example response plots

See also

References