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001 978-3-319-91560-9
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008 180620s2019 sz | s |||| 0|eng d
020 _a9783319915609
_9978-3-319-91560-9
024 7 _a10.1007/978-3-319-91560-9
_2doi
050 4 _aTK5102.9
072 7 _aTJF
_2bicssc
072 7 _aUYS
_2bicssc
072 7 _aTEC008000
_2bisacsh
072 7 _aTJF
_2thema
072 7 _aUYS
_2thema
082 0 4 _a621.382
_223
100 1 _aStrobel, Rainer.
_eauthor.
_4aut
_4http://id.loc.gov/vocabulary/relators/aut
_953572
245 1 0 _aChannel Modeling and Physical Layer Optimization in Copper Line Networks
_h[electronic resource] /
_cby Rainer Strobel.
250 _a1st ed. 2019.
264 1 _aCham :
_bSpringer International Publishing :
_bImprint: Springer,
_c2019.
300 _aXIII, 200 p. 117 illus., 98 illus. in color.
_bonline resource.
336 _atext
_btxt
_2rdacontent
337 _acomputer
_bc
_2rdamedia
338 _aonline resource
_bcr
_2rdacarrier
347 _atext file
_bPDF
_2rda
490 1 _aSignals and Communication Technology,
_x1860-4870
505 0 _aIntroduction to Fast Digital Access and FTTdp Networks -- Channel Models for Twisted Pair Cable Bundles -- Precoding Optimization for Copper Line Networks -- Framing-Based Optimization -- Conclusion.
520 _aThis book investigates the physical layer aspects of high-speed transmission on twisted-pair copper wires, where the most performance-critical components are multi-input multi-output (MIMO) precoding and multi-line spectrum optimization as well as optimized scheduling of the transmission time slots on the fiber to the distribution point (FTTdp) copper link. The book brings theoretical results into the implementation, which requires the introduction of realistic channel models and more practical implementation constraints as found in the copper access network. A good understanding of the transmission medium, twisted-pair telephone cable bundles is the basis for this work. Starting from the analysis of measurement data from twisted-pair cable bundles at high frequencies, it presents a MIMO channel model for the FTTdp network, which allows the characteristic effects of high-frequency transmission on copper cable bundles in simulation to be reproduced and the physical layer transmission methods on the copper channels to be analyzed and optimize. The book also presents precoding optimization for more general power constraints and implementation constraints. The maximization of data rate in a transmission system such as G.fast or VDSL is a combinatorial problem, as the rate is a discrete function of the number of modulated bits. Applying convex optimization methods to the problem offers an efficient and effective solution approach that is proven to operate close to the capacity of the FTTdp channel. In addition to higher data rates, low power consumption is another important aspect of the FTTdp network, as it requires many access nodes that are supplied with power from the subscriber side over the twisted- pair copper wires. Discontinuous operation is a method of quickly adding and removing lines from the precoding group. To implement this, the system switches between different link configurations over time at a high frequency. The transmission times of all lines are jointly optimized with respect to the current rate requirements. Discontinuous operation is used to save power, but also makes it possible to further increase the data rates, taking the current subscriber traffic requirements into account. These methods are compared with theoretical upper bounds, using realistic channel models and conditions of a system implementation. The performance analysis provides deeper insights into implementation complexity trade-offs and the resulting gap to channel capacity.
650 0 _aSignal processing.
_94052
650 1 4 _aSignal, Speech and Image Processing .
_931566
710 2 _aSpringerLink (Online service)
_953573
773 0 _tSpringer Nature eBook
776 0 8 _iPrinted edition:
_z9783319915593
776 0 8 _iPrinted edition:
_z9783319915616
776 0 8 _iPrinted edition:
_z9783030062545
830 0 _aSignals and Communication Technology,
_x1860-4870
_953574
856 4 0 _uhttps://doi.org/10.1007/978-3-319-91560-9
912 _aZDB-2-ENG
912 _aZDB-2-SXE
942 _cEBK
999 _c79174
_d79174