Difference between revisions of "Jitter"
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Because of the difference between the ideal signal and the real signal, the transition between a “1” and a “0” or between 5 Volts and 0 Volts takes a finite amount of time; which is referred to as the “rise time” or “fall time.” Thus a threshold is needed to decide ''when'' the signal has changed from a “0” to a “1” (or vice-versa) and this is a voltage (amplitude) threshold which does not change by design. If either the amplitude of the signal or the “slope” (rise/fall time) of the signal changes; the signal will cross the threshold at a ''different time''; thus effectively changing the amplitude variation into a timing variation. | Because of the difference between the ideal signal and the real signal, the transition between a “1” and a “0” or between 5 Volts and 0 Volts takes a finite amount of time; which is referred to as the “rise time” or “fall time.” Thus a threshold is needed to decide ''when'' the signal has changed from a “0” to a “1” (or vice-versa) and this is a voltage (amplitude) threshold which does not change by design. If either the amplitude of the signal or the “slope” (rise/fall time) of the signal changes; the signal will cross the threshold at a ''different time''; thus effectively changing the amplitude variation into a timing variation. | ||
| − | There are a number of sources of jitter, and in signal transmission between equipment the primary cause is “reflections” of the signal by impedance miss-matches in the signal path caused by things like connectors or differences in the impedance of cable and wiring on either side of a connector. Much like ripples on the surface of a pond, the “waves” add or subtract from each other in a complex changing pattern that results in changes to the shape of the transmitted waveform. These variations cause the waveform to cross the voltage threshold at different times than the transitions of the original signal; resulting in a time-domain distortion regardless of whether the distortion of the shape of the waveform was in the | + | There are a number of sources of jitter, and in signal transmission between equipment the primary cause is “reflections” of the signal by impedance miss-matches in the signal path caused by things like connectors or differences in the impedance of cable and wiring on either side of a connector. Much like ripples on the surface of a pond, the “waves” add or subtract from each other in a complex changing pattern that results in changes to the shape of the transmitted waveform. These variations cause the waveform to cross the voltage threshold at different times than the transitions of the original signal; resulting in a time-domain distortion regardless of whether the distortion of the shape of the waveform was in the time domain or the amplitude domain. |
| − | http://en.wikipedia.org/wiki/Jitter | + | [http://en.wikipedia.org/wiki/Jitter For more information on the jitter click here] |
[[Category:Terminology]] | [[Category:Terminology]] | ||
Revision as of 12:53, 29 March 2012
Overview
The term "jitter" is used to describe variations in a periodic signal, which can be in the frequency, amplitude, or "phase" of the signal in relationship to the idea form or the form at the point of generation. In digital audio; one of the most problematic issues involving jitter is in "clock recovery" from signals transmitted between equipment. If jitter in the recovered clock signal affects the clocking of the conversion, even small amounts of jitter can effectively reduce the resolution to far below the theoretical limits of 16-24 bit conversion.
Basics
Because even "digital" signals are actually very high frequency analog signals, the receiving device must reconstruct the signal by means of some form of amplitude "threshold." Ideal digital signals have a "zero rise time and zero fall time" which means the change in voltage level between a "1" and a "0" requires no time. In digital circuitry, a "1" is represented by a voltage level very close to the power supply voltage; which in digital circuitry is a value like 5 Volts or 3.3 Volts. In the same circuitry, a “0” is represented by a voltage level very close to “0 Volts” or in other words “ground.” In order to reduce power dissipation, power supply voltages are being reduced further; but that is beyond the scope of this discussion.
Because of the difference between the ideal signal and the real signal, the transition between a “1” and a “0” or between 5 Volts and 0 Volts takes a finite amount of time; which is referred to as the “rise time” or “fall time.” Thus a threshold is needed to decide when the signal has changed from a “0” to a “1” (or vice-versa) and this is a voltage (amplitude) threshold which does not change by design. If either the amplitude of the signal or the “slope” (rise/fall time) of the signal changes; the signal will cross the threshold at a different time; thus effectively changing the amplitude variation into a timing variation.
There are a number of sources of jitter, and in signal transmission between equipment the primary cause is “reflections” of the signal by impedance miss-matches in the signal path caused by things like connectors or differences in the impedance of cable and wiring on either side of a connector. Much like ripples on the surface of a pond, the “waves” add or subtract from each other in a complex changing pattern that results in changes to the shape of the transmitted waveform. These variations cause the waveform to cross the voltage threshold at different times than the transitions of the original signal; resulting in a time-domain distortion regardless of whether the distortion of the shape of the waveform was in the time domain or the amplitude domain.