SDH and WDM: a look at the physical layer



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SDH and WDM: a look at the physical SDH and WDM A look at the physical Andrea Bianco Telecommunication Network Group firstname.lastname@polito.it http://www.telematica.polito.it/ Network management and QoS provisioning - 1 Copyright This work is licensed under the Creative Commons Attribution-NonCommercial- ShareAlike 3.0 Unported License. To view a copy of this license visit: http://creativecommons.org/licenses/by-ncsa/3.0/ or send a letter to Creative Commons, 559 Nathan Abbott Way, Stanford, California 94305, USA Network management and QoS provisioning - 2 Physical (not only in telephone networks) TDM based scheme No store and forward in nodes Two technologies Plesiouchronous Digital Hierarchy (PDH) No global network synchronization T and E hierarchies Synchronous Digital Hierarchy (SDH) Global network synchronization Fiber based (optical) transmission Phone channels named Network management and QoS provisioning - 3 Pag. 1

SDH and WDM: a look at the physical PDH: T and E hierarchies Level USA (T-) Europe (E-) Japan 0 0.064 Mb/s 0.064 Mb/s 0.064 Mb/s 1 1.544 Mb/s 2.048 Mb/s 1.544 Mb/s 2 6.312 Mb/s 8.488 Mb/s 6.312 Mb/s 3 44.736 Mb/s 34.368 Mb/s 32.064 Mb/s 4 274.176 Mb/s 139.264 Mb/s 97.928 Mb/s Network management and QoS provisioning - 4 USA: T-1 carrier system Frame duration 125µs One sample (8bit) per channel every 125µs 24 TDM PCM channels Transmission rate (24*8+1)*8000=1.544Mb/s 1 signalling channel (1 bit per frame) No support for management functions CH1 CH2... CH23 CH24 Sample MUX Frame S CH1 CH2 CH3... CH22 CH23 CH24 x x x x x x x x MSB LSB Network management and QoS provisioning - 5 T- and DS- hierarchy S CH1 CH2 CH3... CH22 CH23 CH24 DS1 DS1 DS1 DS1 64 24+8k=1.544 Mb/s T1 Frame transmitted over a DS1 Difficult to have perfect synchronization between ALL nodes. bit stuffing to overcome it. DS2 DS2 DS2 DS2 DS2 DS2 DS2 DS3 DS3 DS3 DS3 DS3 DS3 DS4 4 DS1 = 1 DS2 4 1.544 = 6.312 Mb/s 7 DS2 = 1 DS3 7 6.312 = 44.736 Mb/s 6 DS3 = 1 DS4 6 44.736 = 274.176 Mb/s Difficult to access a single channel in a high-speed stream: de-multiplexing of all must be performed Similar solutions in Europe and Japan, although with different speed. Interoperability issues Network management and QoS provisioning - 6 Pag. 2

SDH and WDM: a look at the physical PDH: synchronization Each device has its own clock (no network wide global synchronization) Local clocks would lead to synchronization errors To solve it TXs faster than receiversers Short buffer to store in transit bits Insert bits through bit stuffing at the end of a frames Stuffed bits must be signalled to the other end to permit bit removal Network management and QoS provisioning - 7 PDH limitations Lack of efficiency Difficult to extract slower from high speed aggregates Lack of flexibility No monitoring standard No management standard No common physical standard Every manufacturer goes alone No NNI standard Network management and QoS provisioning - 8 SONET/SDH Exploits network-wide synchronizaton Hierarchies SONET - Synchronous Optical NETwork Used in USA Based on fiber transmission Base signal at 51.84 Mbit/s SDH - Synchronous Digital Hierarchy International and European Base signal at 155.52 Mbit/s STS - Synchronous Transport Signal Labels to identify electrical signals Introduction of management, signalling, protection Network management and QoS provisioning - 9 Pag. 3

SDH and WDM: a look at the physical SONET/SDH Goals Main goals of SONET/SDH: Fault tolerance as required by telecom providers 99.999%, or five nines availability Interoperability among different manufacturers Flexibility of upper formats to adapt to different source (not only voice) Complex monitoring capabilities of performance and traffic 50 ms of recovery time after failure Network management and QoS provisioning - 10 SONET/SDH OC level STS level SDH level Mbit /s OC-1 STS-1 51.84 OC-3 STS-3 STM-1 155.52 OC-12 STS-12 STM-4 622.08 OC-24 STS-24 STM-8 1244.16 OC-48 STS-48 STM-16 2488.32 OC-192 STS-192 STM-64 9953.28 OC-768 STS-768 STM-256 39813.12 OC-3072 STS-3072 STM-1024 159252.48 Network management and QoS provisioning - 11 SONET/SDH framing Continuous bit transmission Complex TDM scheme Designed to permit a very efficient VLSI implementation Each frame includes a PCI (Protocol Control Information) or overhead which includes Synchronization infos Voice channels for OAM services Support for complex fault/error management procedures Layered architecture Path, Line, Section (each including overhead infos) Network management and QoS provisioning - 12 Pag. 4

SDH and WDM: a look at the physical Layering in SONET/SDH standard ITU-T G.78x path path line line line ayer physical physical physical physical Terminal R o DCX Terminal regenerator add/drop mux or digital cross connect Network management and QoS provisioning - 13 SONET/SDH reference model Path (similar to OSI 3) Manages end-to-end connections Monitoring and management of user connection Line Layer (similar to OSI 2) Multiplexing of several path- connection among nodes Protection and Fault Management Section Layer (similar to OSI 2-1) Frame alignment Define regenerator functions Photonic Layer (same as OSI 1) Defines all the transmission requirements of signals. Network management and QoS provisioning - 14 SONET: Framing STS-1 0 µs 90 byte 3 byte 87 byte A1 Framing A2 C1 B1 E1 F1 D1 D2 D3 H1Puntatori H2 H3 B2 K1 K2 D4 D5 D6 D7 D8 D9 D10 D11 D12 Z1 Z2 E2 Section overhead Payload J1 B3 C2 G1 F2 H4 Z3 Z4 Z5 Line overhead Payload Path overhead 125µs Network management and QoS provisioning - 15 Pag. 5

SDH and WDM: a look at the physical SONET/SDH: overhead Section Framing Parity check Voice channel for operators OAM and protection Line Pointers to indentify payload Parity check Performance monitoring Automatic protection switching(signalling to face fault management) Support for restoration Synchronization info distribution Voice channel for operators Path End to end monitoring Network management and QoS provisioning - 16 SONET/SDH equipment Regenerators 3-R functions SOH processing and regeneration Two multiplexer types Terminal multiplexer (TM) PDH and SDH Add-drop multiplexer () PDH and SDH Used in ring topologies Transit traffic forwarded transparently Digital cross-connect PDH and SDH Operate links with different speed PDH/SDH STM - N STM-N PDH/SDH PDH/SDH STM - N STM-N STM-N PDH/SDH Network management and QoS provisioning - 17 SONET/SDH transport scheme Transport of digital through SDH equipment MPX DXC R R MPX STM-n STM-n STM-n STM-n t i Multiplexing Lower-order path Regeneration Regeneration Multiplexing Higher-order path Lower-order path Regeneration Network management and QoS provisioning - 18 Pag. 6

SDH and WDM: a look at the physical SONET/SDH Network Configurations Point-to-point topology Simplest topology The point-to-point start and end on a PTE (Path Terminating Equipment), which manages the mux/demux of t i No routing, and no demux along the path Regenerators may be used to cope with transmission problems PTE REG REG REG REG PTE Network management and QoS provisioning - 19 SONET/SDH Network Configurations Linear add-drop topology Still a linear topology (and regen) along the line allow to add and drop along the path are designed to work in this kind of simple topologies, which often translates to rings there is no need to mux and remux in transit PTE REG REG REG REG PTE Network management and QoS provisioning - 20 SONET/SDH Network Configurations Hub network setup Typically on large aggregation point Adopt Digital Cross connect (DCX) working at high rate DCXs are much more complex that s they have to manage both single tributary and SONET stream Meshed topologies Often seen as interconnected rings REG Mux Mux REG DCX REG Mux Mux REG Network management and QoS provisioning - 21 Pag. 7

SDH and WDM: a look at the physical SONET Network Configurations SONET Rings The most used topology. Can use two or four fibers and an at each node Bidirectional topology Simple protection functions against single failure Bidirectional ring becomes unidirectional ring SONET Ring Architecture Network management and QoS provisioning - 22 WDM: Optical transmission (and more?) Fibers can carry huge bandwidth Signals are generated in the electronic domain Limited ability to exploit the optical bandwidth Today 10Gbit/s transmission systems are the standard commercial for high speed transmission 40Gbit/s are the next step Still a huge bandwidth gap WDM (a FDM technique well suited to the optical domain) Many wavelengths on a single fiber Each wavelength transport an independent electronic signal 128 2.5 Gbit/s or 32 10 Gbit/s Network management and QoS provisioning - 23 WDM for optical networks Which functions can be performed in optics? Transmission Switching/routing Implies buffering? Management First generation optical networks Optics for transmission only Second generation optical networks Perform also switching/routing in the optical domain Wavelength routing approach Network management and QoS provisioning - 24 Pag. 8

SDH and WDM: a look at the physical Wavelength Routing (WR) networks WDM is exploited to route and switch information in the optical domain using wavelengths Transparent or opaque optical circuits, called lightpaths, are used to connect network nodes. Lightpaths are optical circuits that may span one or more hops in the physical topology, and may cross switching elements in the optical Traffic carried by a lightpath may be packet-based, e.g., IP datagrams circuit oriented, e.g., telephone streams. The optical network is not aware of traffic formats Network management and QoS provisioning - 25 WR approach Network nodes Optical links Transparent lightpath #1 Transparent lightpath #2 RX TX RX TX Network management and QoS provisioning - 26 WR devices In a wavelength routed network Optical Line Terminal (OLT): line termination, taking care of physical functions, signal regeneration, wavelength adaptation, amplification, traffic multiplexing/demultiplexing Optical Add-Drop Multiplexer (O): it allows to add and drop traffic carried by one or more wavelengths in a (bidirectional) WDM link Optical Cross Connect (OXC): switches incoming wavelengths to multiple outgoing fibers These devices are similar to the equivalent firstgeneration SONET/SDH devices Network management and QoS provisioning - 27 Pag. 9

SDH and WDM: a look at the physical WR network architecture OLT OLT OXC OXC IP router O O O O SONET terminal Network management and QoS provisioning - 28 Pag. 10

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