In telecommunications and electronics, a self-clocking signal is one that can be decoded without the need for a separate clock signal or other source of synchronization. This is usually done by including embedded synchronization information within the signal, and adding constraints on the coding of the data payload such that false synchronization can easily be detected.
If a clock signal is embedded in the data transmission, there are two possibilities: the clock signals are sent at the same time as the data (isochronous), or at a different time (anisochronous).
Isochronous self-clocking signals
If the embedded clock signal is isochronous, it gets sent simultaneously with the data. Below is an example signal, in this case using the Manchester code self-clocking signal. The data and clock cycles can be thought of as "adding up" to a combination, where both the clock cycle and the data can be retrieved from the transmitted signal.
Asynchronous self-clocking signals
Asynchronous self-clocking signals do not combine clock cycles and data transfer into one continuous signal. Instead, the transmission of clock cycles and data transmission is modulated. Below is an example signal used in asynchronous serial communication, where it is made clear that the information about the clock speed is transmitted in a different timeframe than the actual data.
Implementations
Example uses of self-clocking signal protocols include:
Most of these codes can be seen as a kind of Run Length Limited[1] code. Those constraints on "runs" of zeros and "runs" of ones ensure that transitions occur often enough to keep the receiver synchronized.
Such self-clocking signals can be decoded correctly into a stream of bits without bit slip. To further decode that stream of bits and decide which bit is the first bit of a byte, often a self-synchronizing code is used.
is self-clocking, as the zero crossings serve as a clock pulse.
One may consider this clock pulse redundant information, or at least a wasteful use of channel capacity, and duplex the channel by varying the phase, as in polar modulation, or adding another signal that is 90° out of phase (a sine wave), as in quadrature modulation. The result is to send twice as many signals over the channel, at the cost of losing the clock, and thus suffering signal degradation in case of clock drift (the analog equivalent of bit drift).
This demonstrates how encoding clocking or synchronization in a code costs channel capacity, and illustrates the trade-off.
^Kees Schouhamer Immink (December 1990). "Runlength-Limited Sequences". Proceedings of the IEEE. 78 (11): 1745–1759. doi:10.1109/5.63306. A detailed description is furnished of the limiting properties of runlength limited sequences.
January 06, 2023
self, clocking, signal, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, feb. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Self clocking signal news newspapers books scholar JSTOR February 2018 Learn how and when to remove this template message In telecommunications and electronics a self clocking signal is one that can be decoded without the need for a separate clock signal or other source of synchronization This is usually done by including embedded synchronization information within the signal and adding constraints on the coding of the data payload such that false synchronization can easily be detected Most line codes are designed to be self clocking Contents 1 Isochronicity and anisochronicity 1 1 Isochronous self clocking signals 1 2 Asynchronous self clocking signals 2 Implementations 3 Analog examples 4 See also 5 ReferencesIsochronicity and anisochronicity EditIf a clock signal is embedded in the data transmission there are two possibilities the clock signals are sent at the same time as the data isochronous or at a different time anisochronous Isochronous self clocking signals Edit If the embedded clock signal is isochronous it gets sent simultaneously with the data Below is an example signal in this case using the Manchester code self clocking signal The data and clock cycles can be thought of as adding up to a combination where both the clock cycle and the data can be retrieved from the transmitted signal Asynchronous self clocking signals Edit Asynchronous self clocking signals do not combine clock cycles and data transfer into one continuous signal Instead the transmission of clock cycles and data transmission is modulated Below is an example signal used in asynchronous serial communication where it is made clear that the information about the clock speed is transmitted in a different timeframe than the actual data Implementations EditExample uses of self clocking signal protocols include Isochronous Manchester code where the clock signals occur at the transition points Plesiochronous Digital Hierarchy signals Eight to Fourteen Modulation 4B5B 8b 10b encoding HDLC Modified Frequency Modulation Anisochronous Morse code Asynchronous start stopMost of these codes can be seen as a kind of Run Length Limited 1 code Those constraints on runs of zeros and runs of ones ensure that transitions occur often enough to keep the receiver synchronized Such self clocking signals can be decoded correctly into a stream of bits without bit slip To further decode that stream of bits and decide which bit is the first bit of a byte often a self synchronizing code is used Analog examples EditAmplitude modulation modulating a signal M t displaystyle M t by changing the amplitude of a carrier wave as in y t M t cos w c t displaystyle y t M t cdot cos omega c t is self clocking as the zero crossings serve as a clock pulse One may consider this clock pulse redundant information or at least a wasteful use of channel capacity and duplex the channel by varying the phase as in polar modulation or adding another signal that is 90 out of phase a sine wave as in quadrature modulation The result is to send twice as many signals over the channel at the cost of losing the clock and thus suffering signal degradation in case of clock drift the analog equivalent of bit drift This demonstrates how encoding clocking or synchronization in a code costs channel capacity and illustrates the trade off See also EditDelay insensitive circuitReferences Edit Kees Schouhamer Immink December 1990 Runlength Limited Sequences Proceedings of the IEEE 78 11 1745 1759 doi 10 1109 5 63306 A detailed description is furnished of the limiting properties of runlength limited sequences Retrieved from https en wikipedia org w index php title Self clocking signal amp oldid 1119563049, wikipedia, wiki, book, books, library,
