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A method of modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing. The method includes the steps of: identi

A method of modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing. The method includes the steps of: identifying select ones of the input data bits which repeat the data state of a respectively preceding one of the input data bits; identifying select ones of the pulses which correspond to the select bits; and, alternately shortening and lengthening the periods associated with the select ones of the pulses.

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1. A method of modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said method comprising the steps of:

1. A method of modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said method comprising the steps of: identifying select ones of said input data bits which repeat the data state of a respectively preceding one of said input data bits; identifying select ones of said pulses which correspond to said select bits; and, alternately shortening and lengthening said periods associated with said select ones of said pulses. 2. The method of claim 1, further comprising: dividing said associated period for each of said pulses into a plurality of temporal apertures.3. The method of claim 2, wherein said alternately shortening and lengthening said period comprises: selecting a first and a second number of said apertures; reversing a phase associated with each select pulse after said first number of apertures in a first mode; and, reversing said phase associated with each select pulse after said second number of apertures in a second mode. 4. The method of claim 1, wherein said alternately shortening and lengthening said period further comprises, alternating between said first and second modes each time it a select bit is identified.5. The method of claim 4, further comprising: selecting a third number of said plurality of apertures; reversing said phase of each other of said pulses after said third number of apertures in a third mode. 6. The method of claim 5, wherein each said preceding bit immediately precedes one of said select bits, respectively.7. The method of claim 5, wherein: said third number is greater than said first number; and, said second number is greater than said third number. 8. The method of claim 7, wherein said third number of apertures corresponds to said associated temporal duration.9. The method of claim 1, wherein positive and negative excursions for each of said pulses are one bit width wide, plus or minus a small fraction of said bit width so as to keep the bit widths continuously changing plus or minus by equal amounts during long periods of transmitted marks or spaces.10. The method of claim 1, wherein a start of a string of ones or zeros as said input bits is indicated by a shortened or lengthened pulse width, followed immediately by a width change in an opposite direction.11. The method of claim 1, wherein a frequency spectrum resulting from said modulation is a substantially single frequency line at ½ the bit rate without visible frequency or phase modulation, but which is detectable from bipolar phase reversals.12. The method of claim 11, further comprising: doubling the single frequency spectral line to yield a data clock signal.13. The method of claim 1, further comprising introducing strings of ones or zeros to reset the clock repeatedly on only one time boundary edge, to prevent a shift in clock timing.14. The method of claim 1, further comprising: filtering off Fourier products without loss of phase change magnitude.15. The method of claim 1, further comprising single sideband suppressed carrier modulating a carrier signal to produce a single spectral frequency alternating in phase at a desired frequency.16. The method of claim 15, wherein the encoded single sideband frequency is added to analog TV signals on a cable distribution system to add digital channels between analog channels without substantially interfering with the analog channels.17. A modulator for modulating a bipolar signal including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said modulator comprising: means for identifying select ones of said input data bits which repeat the data state of a respectively preceding one of said input data bits; means for identify ing select ones of said pulses which correspond to said select bits; and, means for shortening and lengthening said periods associated with said select ones of said pulses. 18. A filter suitable for use in modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said filter comprising: a transformer including first and second secondary nodes; a first capacitor coupled to said first node; a crystal oscillator coupled to said second node; and, a second capacitor coupled to said second node; wherein, when the crystal oscillator is excited by a narrow band rapidly phase reversing signal frequency acts as a reference element only. 19. A filter suitable for use in modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said filter comprising: a reference resonator having a group delay; and, a signal path that bypasses the resonator, such that the group delay of the resonator does not factor in transmission of said modulated pulses, but determines a bandwidth of the filter by virtue of said resonator being used as an impedance reference only. 20. The filter of claim 19, wherein the reference resonator is operated in a parallel mode, has a high impedance at a frequency associated with said temporal duration such that said pulses do not pass through it, and provides negative feedback at frequencies off resonance.21. The filter of claim 19, wherein said reference resonator is operated in a series mode, provides positive feedback that accentuates the gain of the filter at a resonant frequency, and is not in a signal of said modulated pulses.22. The filter of claim 19, wherein the reference resonator is independent of a group delay of the filter.23. A method of digital data encoding a multiplicity of data bits, each having a data state, to cause a phase or polarity reversal each bit period while changing the temporal duration of each bit period to encode the data, the said method comprising the steps of: identifying the data state of the last incoming bit; alternately shortening and lengthening duration of the phase reversal period if the bit is repeated; reversing phase or polarity at exactly one bit period if the data state changes from a one to a zero or vice versa. 24. The method of claim 23 in which a series of phase or polarity reversals of duration equal to one bit period represents an alternating one/zero pattern.25. The method of claim 23 in which a repeated digital one is represented by a shortened phase reversal period.26. The method of claim 23 in which a repeated digital zero is represented by a shortened phase reversal period.27. The method of claim 25 in which additional repeated bits of the same polarity are represented by alternately shortening and lengthening the phase reversal times relative to a normal bit period.28. The method of claim 23 in which a phase or polarity reversal equal to one bit period represents a change from a one to a zero and vice versa.29. A filter suitable for use in modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said filter comprising: a reference resonator having a group delay independent of a group delay of the filter operated in a parallel mode having a high impedance at a frequency associated with said temporal duration such that said pulses do not pass through it, and provides negative feedback at frequencies off resonance; and, a signal path that bypasses the resonator, such that the group delay of the resonator does not factor in transmission of said modulated pulses, but determines a bandwidth of the filter by virtue of said resonator being used as an impedance reference only. 30. A filter suitable for use in modulating a phase reversing pulse train including a plurality of signal pulses each having an associated period of a given temporal duration to encode a multiplicity of input data bits each having a data state, and prevent losses of clock timing, said filter comprising: a reference resonator having a group delay having a group delay independent of a group delay of the filter operated in a series mode, providing positive feedback that accentuates the gain of the filter at a resonant frequency, and is not in a signal of said modulated pulses; and a signal path that bypasses the resonator, such that the group delay of the resonator does not factor in transmission of said modulated pulses, but determines a bandwidth of the filter by virtue of said resonator being used as an impedance reference only. 31. A digital communication system comprising: a means for modulating a pulse train wherein a Fourier frequency components bearing abrupt changes of phase, each of said Fourier frequency components being a single frequency; and a filtering means operable to pass a selected one of said Fourier frequency components. 32. The system as recited in claim 31, wherein said filter means is a resonator operated as a parallel shunt-tuned reference, having a high infinite impedance at a selected one of said Fourier frequency components wherein said reference is transparent to said selected Fourier frequency component.33. The system as recited in claim 32, wherein said selected Fourier frequency component does not exhibit a group delay associated with said resonator.34. The system as recited in claim 33, wherein said abrupt changes of phase associated with said selected Fourier frequency component pass said filter means without incurring loss of phase change.