General Purpose Video Filters
Faraday Technology design and manufacture
general purpose
video filters for
electronic signal processing. The design of filters is often referred to as a ‘black
art’. With computer aided design it is often relatively easy to produce a
general purpose filter
circuit which satisfies the electrical specification. The main problem, and the reason why
many organisations do not design and make their own filters if the realisation of the
design in size, package type and price required, with the miniaturisation of electronics
the demand for smaller and smaller filters has increased. Thirty years ago it may have
been acceptable to manufacture a filter using silvered mica capacitors and large pot cores
ending in with a box measuring 10 cm square. Today the demand is for the same performance
in a SIL or surface mount device one tenth the size and able to pass through a reflow oven
and be aqueously washed.
The basic parameters which
should be considered when defining or selecting a general purpose filter are,
- Maximum Insertion (basic)
Loss
- Passband Frequencies
- Stopband Frequencies
- Stopband rejections
- Amplitude Ripple in the Passband
- Group Delay (Phase) Ripple in the Passband
- Source and Load Impedance
- Package Type and Size
- Assembly Methods
- Operating Conditions
General Purpose
Video Filters may be divided into five basic types
and categorised according to the technology they use to realise the design that makes them
work.
The five basic types of described in terms of frequency are
low pass, high pass,
band pass, band stop and all pass. Although the descriptions are
self-explanatory the illustrations below describe each and define some of the basic terms
used to specify a filter.
Figure 1 Diagram of Low Pass and High Pass
Figure 2 Band Stop and Band Pass
It would be convenient if the same physical technology
could be used to make filters of any frequency but this is not possible so a range of
methods have been developed over the years according to the frequency range. Analogue
filters range from fully active e.g. using transistors, operational amplifiers and
integrated circuits through passive components, inductors, capacitors and resistors to
resonant cavity where the filter is a series of cavities milled out of a block of metal.
A summary of the manufactory technologies and frequencies
over which they may be used is given as a general guide only.
The range of frequencies covered by a particular technology
is also dependent on the relative bandwidth.
Image Parameter Theory
Until the 1950s filters were designed using what is called
Image Parameter Theory. This theory is based on looking at the impedance of an electronic
network to produce a prototype circuit. It is then possible to cascade many of the
prototype networks together to increase the complexity of the filter. This method had many
problems and in 1923 Zobal published a paper describing a new method of designing filters.
This consisted of producing a polynomial equation to describe the ratio between the input
voltage level and output voltage level in terms of frequency. This is referred to as a
transfer function. By solving the polynomial and calculating the component or element
values a much more exact design may be produced. This method is called Modern Network
Theory.
As modern network theory involves prodigious amounts of
calculation to solve the equations it only became a practical method when computers were
generally available.
Frequency Band
It would be ideal if a filter could be made to pass a
certain frequency band but then immediately reject an adjacent band but this is not
possible. There is always an area or band transition between the region of pass and the
region of reject. The slower this transition is the simpler the filter can be.
A number of standard transfer functions were derived by
various researchers to solve specific problems. These have become standard topographies
and most relate to the speed of the transition from the end of the passband to the start
of the stop band.
Well Known Filters
The most well known filters are shown below in terms of Loss and
group Delay against Frequency. The fundamental difference is the cut off rate and the
shape of the group delay response. These basic topographies may be used whatever the final
method of realisation of the filter.
Butterworth Filter
Bessel Filter
Linear Phase Filter
Chebyshev Filter
Elliptical Function ( Cauer ) Filter
Considering a Filter
When considering a general purpose filter it is important to give
consideration to the degradation the filter produces in the signal that it is required to
pass. The effect may be categorised as follows,
Insertion Loss or Basic Loss
Insertion Delay
Amplitude – Frequency Response
Group Delay (Phase) – Frequency Response |
The insertion loss may be corrected using
amplifiers but the insertion delay is inherent and cannot be removed. The other
distortions can be corrected by adding amplifiers and or equalisers.
Time Domain Response
An additional consideration is the Time Domain Response.
This is often missed because most general purpose filter design is done in the frequency domain, but as
real world operates in the time domain when a filter is introduced into a circuit the
results can be poor due to time domain ringing, even though the filter is working in the
frequency domain as specified. All filters engineer’s have received panic calls from
customers saying "but my system has ringing, what can you do about it?" The
answer is often to use a different and ‘softer’ roll-off filter.
Group Delay Equalisation
As a basic rule the faster the filter cuts off in the
frequency domain the more time domain distortion and ringing it will introduce. Group
delay equalisation moves the energy of the ringing to be more symmetrical about a pulse of
impulse which make the effect more acceptable but it is a common fallacy to think that
ringing can be removed by equalisation.
Analogue Filters
With analogue filters it is important to specify a source
and load impedance. In low frequency and audio systems it is normal to have high input and
low output impedance. This is easily achieved when active elements are employed. At higher
frequencies where inductors and capacitors are used it is normal to specify a transmission
line impedance. With this type of filters it is important realise that power cannot be
absorbed (except due to the inherent resistance in the components) and a filter rejects by
reflecting the power back down the line. This is achieved by the general
purpose filter changing its
impedance at the interface with the source. A good source resistance is required to absorb
the reflected power. Comprehensive range of
General Purpose Video Filters
Faraday has specialised in the design and manufacture of filters for the Professional
Broadcast Industry by combining a knowledge of filter design and manufacture with a
knowledge of television technology. It has the most comprehensive range of
general purpose video filters
available. |
