An Experimental 224 Mb/s Digital Repeatered Line

Dorros, I.; Sipress, J.; Waldhauer, F.D.

doi:10.1002/j.1538-7305.1966.tb01685.x

Cited by 22 publications

(4 citation statements)

References 18 publications

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“…Starting point for dhensioning is the condition for quasi static phase error. Generally considered to be acceptable with respect to loss in signal to noise ratio is a quasi static phase error of about 0.1 radian [15]. This phase error is a result of the following imperfections: 1) drift of the quiescent VCO (voltage-controlled-oscillator) frequency from the digit frequency.…”

Section: Clock Extractormentioning

confidence: 98%

An Experimental 560 Mbits/s Repeater with Integrated Circuits

Roza

Millenaar²

1977

IEEE Trans. Commun.

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The bandwidth penalty of digital systems is very obvious in the case of transmission over coaxial cables because of the exponential increase of cable attenuation with square root of frequency. From capacity point of view, it is only at very high information rates (> 500Mbit/s typically) that a digital system might be competitive with an analog system, because the disadvantage of noise accumulation in an analog system ultimately cancels the bandwidth penalty of the digital system.In addition, it is, however, difficult to realize common functions, such as amplification, equalization, regeneration, clock extraction, etc. with electronic components having a frequency range comparable to the frequency range of the information signal, which extends from zero frequency to the microwave range. Besides, the complexity of a regenerative repeater should be kept to a minimum for reliability reasons.It is shown in the paper that with present-day technology a 560 Mbit/s repeater cah be constructed, operating in sections of 1.5 km coaxial cable (2.6/9.5 mm). Also, we demonstrate that new technologies exist which may lead to repeaters with a high degree of monolithic integration, even at such a speed, which is important from the reliability viewpoint. The constructed and described repeater is characterized by unconventional and economic design of amplifier/equalizer and clock extractor and by monolithically integrated decision circuits.

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Section: Clock Extractormentioning

confidence: 98%

An Experimental 560 Mbits/s Repeater with Integrated Circuits

Roza

Millenaar²

1977

IEEE Trans. Commun.

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“…It is well known that the insertion-loss characteristic of a high-frequency coaxial transmission line with attenuation due to skin effect is of the form [4], [5] C(S) = e -STe-1kJS . (1) The first factor of the expression corresponds to a pure delay, whose exact value is of little concern in waveform transmission.…”

Section: Multipath Lb0 Structurementioning

confidence: 99%

“…In the case of high-speed PCM baseband transmission systems [5], the timing circuit seeks the pulse peak and locks onto it, while the automatic gain control (AGC) circuit automatically adjusts the peak amplitude to a nominal (unity) value. To explore the application of a multipath adjustable LB0 within such a system, the simulation scheme of Fig.…”

Section: Time-domain Error With a Pulseinputmentioning

confidence: 99%

Analysis of an adjustable multipath network for use in building out transmission-line skin-effect losses

Chen¹

1971

IEEE Trans. Circuit Theory

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“…One satisfactory way to treat buffer overflow is to let bi«o of (1) change during time interAals when the integral would otherwise cause (14) In exploring the effect of buffer overload it is sufficient to consider a circuit element consisting of an inductor and two bias currents. For simplicity we will assume that these bias currents are equal and opposite, with magnitudes lo, as shown in Fig.…”

Section: Jamentioning

confidence: 99%

Synchronizing Digital Networks

Pierce¹

1969

Bell System Technical Journal

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An Experimental 224 Mb/s Digital Repeatered Line

Cited by 22 publications

References 18 publications

An Experimental 560 Mbits/s Repeater with Integrated Circuits

An Experimental 560 Mbits/s Repeater with Integrated Circuits

Analysis of an adjustable multipath network for use in building out transmission-line skin-effect losses

Synchronizing Digital Networks

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