Everything about Insertion Loss totally explained
In
telecommunications,
insertion loss is the decrease in transmitted
signal power resulting from the insertion of a device in a
transmission line or
optical fiber. It is usually expressed relative to the signal power delivered to that same part before insertion. Insertion loss is usually expressed in
decibels (dB).
The insertion loss of a device (which may be a whole line) may also be referred to as
attenuation. Line terminations play an important part in insertion loss because they reflect some of the power. Apart from this it's clear that not all of the power which is sent into the line at one end appears at the other. This is because of radiation losses, resistive losses in the conductor as well as losses in the surrounding dielectric. All of these effects can be conceptually modelled as various elements which make up the equivalent circuit of the line (see for example
distributed and
lumped element models). The loss which results from inserting a transmission line between a source and a load is called the
insertion loss of the line.
If the power transmitted by the source is
PT and the power received by the load is
PR, then the insertion loss is given by
PR divided by
PT. For maximum power transfer the insertion loss should be as small as possible. In other words, the ratio
PR/
PT should be as close to 1 as possible, which in decibels means as close to 0dB as possible.
In an optical fiber system, insertion loss is introduced by things such as
connectors,
splices, and couplers.
Insertion Loss Testing
Filters are generally specified with insertion loss performance data. Insertion loss is defined as a ratio of the signal level in a test configuration without the filter installed (V1) to the signal level with the filter installed (V2). This ratio is generally described in db according to the following equation:
Insertion loss (db) = 20 log (V1/V2)
Filters are sensitive to source and load impedances so the exact performance of a filter in a circuit is impossible to precisely predict. Comparisons, however, of filter performance are possible if the insertion loss measurements are made with fixed source and load impedances. 50 ohms is the universally accepted measurement impedance. This data is currently specified as common-mode or differential-mode. Common-mode simply put, is a measure of the filter performance on signals that originate between the power lines and chassis ground. Differential-mode is a measure of the filter performance on signals that originate between the "hot" and neutral power lines. Common-mode insertion loss is measured by connecting the line and neutral terminals together and using the test configuration of figure 1.
Differential-mode insertion loss is measured by using the 180 degree power splitters and using the test configuration of figure 2.
Further Information
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