SONET/SDH. the current standard for high speed carrier infrastructure in North America. the European counterpart (closely related).

Transcription

1 SONET/SDH

2 SONET/SDH! SONET (Synchronous Optical Network) is the current standard for high speed carrier infrastructure in North America.! SDH (Synchronous Digital Hierarchy) is the European counterpart (closely related).! Before SONET/SDH, the infrastructure was based on PDH (Plesiochronous (or asynchronous) Digital Hierarchy 1960s).

3 PDH

4 PDH! A 4kHz band limited signal (voice) can be sampled with 8kHz and quantized at 8 bits/sample resulting in 64kbps.! Higher bit rates are multiples of this bit rate and are offered as leased line speeds: North America Europe Japan Level Name Bit Rate Name Bit Rate Name Bit Rate 0 DS0 64k E0 64k J0 64k 1 DS M E M J M 2 DS M E M J M 3 DS M E M J M 4 DS M E M J M

5 Problems with PDH 1. Each terminal (switch) in the network runs its own clock, thus actual rates and offsets can be huge (bit rate differences up to 1.8kbps).! This means that when slower speed signals are multiplexed by interleaving their bits, extra bits need to be stuffed into the new stream.! In PDH, bit rates are not exact multiples of lower bit rates (e.g. 24*64k=1.536M 1.544M)

6 Problems with PDH 2. It is difficult to pick out (drop) a low bit rate stream out of a high bit rate stream w/o completely demultiplexing the stream.! Multiplexer mountains (stacked up).! Expensive and compromises network reliability (large amount of electronics).

7 SONET/SDH

8 Solution: SONET! All the clocks in the network are synchronized to a single master.! => rates are integral multiples of the basic rate.! => no bit stuffing is needed! => lower-speed signals can be extracted from a multiplexed SONET stream easily.

9 Solution: SONET! Management: extensive management information for managing the network:! Performance monitoring! Identification of traffic type! Identification of connectivity! Identification and reporting of failures! Data channels between nodes for management info

10 Solution: SONET! Interoperability: (PDH did not define standard formats, thus different vendors used different coding, interfaces, etc.)! Standard optical interfaces! But some issues were standardized too late, thus even today it is not trivial to interconnect SONET equipment of different vendors.

11 Solution: SONET! Network availability:! Specific network topologies are supported (point-to-point, ring, linear add-drop)! => service restoration time is less than 60ms (while with PDH it was up to several minutes)

12 SONET Multiplexing! Easily implemented in VLSI.! SONET and SDH terms are unfortunately very different.! SONET basic rate is 51.48Mbps (STS-1 ; synchronous transport signal).! Higher rate signals are obtained by interleaving the bytes of N (aligned) frames (STS-N) (scrambling is used to prevent long runs of 0s or 1s)

13 SONET/SDH/OC Rates SONET Signal SDH Signal Optical Carrier Bit Rate [Mbps] STS STS-3 STM-1 OC STS-12 STM-4 OC STS STS-48 STM-16 OC STS-192 STM-24 OC STS-768 STM-256 OC ,814.32

14 SONET/SDH Rates! SONET s basic rate is to easily accommodate DS1 and DS3 signals, while SDH s objective was to accommodate E1,E3 and E4 signals.! The frame structure makes extensive use of pointers to indicate the location of payload in the frame (payload is not fixed in the frame). This is required because off clock offsets and transients.

15 SONET Multiplexing! Non-SONET streams below the STS-1 rate are mapped into Virtual Tributaries (VTs) (or VC virtual containers in SDH). There are 4 different VTs as shown in the next picture.! VTs can also float in an STS-1! STS-Nc signals have locked payload that cannot be further demultiplexed via SONET (e.g., for ATM over SONET).

16 SONET Multiplexing

17 SONET Layers! SONET layer consists of four sub-layers:! Path (end-to-end connections)! Line (protection)! Section! Physical Gergely Zaruba - CSE6344 Fall 2001

18 SONET Frame Structure! Payload is carried in a synchronous payload envelope (SPE). Section and Line overhead 1 column is for Path overhead

19 SONET Frame Structure! STS-N frames are N interleaved STS-1 frames:

20 SONET Overhead Bytes! To scare students Gergely Zaruba - CSE6344 Fall 2001

21 SONET Physical Specs! Short-reach (I) connections (<2km)! Short-haul (S) (15km or 40km)! Long-haul (L) (40km or 80km)! Very-long-haul (V) (60km or 120km)! Ultra-long-haul (U) (160km)! No optical line amplifiers are considered, but with the given parameters and EDFAs regenerators can be placed as far as 600km to a few thousand km. This is vendor dependent as has not been standardized yet.

22 SONET Physical Specs Gergely Zaruba - CSE6344 Fall 2001

23 SONET Physical Specs Gergely Zaruba - CSE6344 Fall 2001

24 SONET Physical Specs

25 SONET Infrastructure! SONET can be deployed as:! Ring! Linear configurations! Point-to-point links! End nodes for point-to-point links are called: Terminal Multiplexers (TMs or line terminating equipment LTE).! ADMs are used to add/drop low speed streams to/from higher speed streams.! ADMs can be inserted between TMs in point-topoint configurations to yield linear configurations.

26 SONET Infrastructure! Maintaining service availability in presence of failures (protection) has become a key driver for SONET deployment => rings are the most common topologies.! Rings consist of ADMs with protection mechanisms.! Usually SONET equipment can be configured to work in any of these configurations

27 SONET Infrastructure! Today most access rings run with OC3/OC- 12 and most interoffice rings run at OC- 12/OC-48/OC-192 (and increasing).! It is common to use multiple overlaid rings (easy with an optical layer).! Two types of ring architectures (protection):! Unidirectional Path Switched Rings (UPSR)! Bi-directional Path Switched Rings (BPSR) with two (BPSR/2) or four fibers (BPSR/4).

28 SONET Infrastructure! Another major component: Digital Crossconnect (DCS)! Can switch PDH signals with software control! Can also switch SONET signals with software control (evolved)! It incorporates multiplexing as well (evolved even more)! DCSs can be narrowband, wideband or broadband, but not all of them at once.! Broad-band DCSs are also called: Optical Crossconnects

29 SONET Infrastructure Gergely Zaruba - CSE6344 Fall 2001

30 ATM

31 Emergence of ATM! Integration of voice and data on a single network! Packet size for voice should be very low (delay) while packet size for data should be large (less overhead).! ATM compromises at 53bytes out of which 5 is the header! ATM spans from LAN through MAN to WAN.! ATM provides for different QoS requirements.

32 Properties of ATM! A priory traffic characteristics are needed (e.g., average and peak bandwidth, average and maximum delay, etc.) for QoS provisioning! ATM is point-to-point and thus employs switching (even in a LAN). Uniform small packet size is good for fast switching.! ATM defines standard interfaces to connect users to local switches (private user-network interface or UNI). Public user-network interfaces (or NNI) are used to connect to carrier networks and use PDH/SONET speeds.

33 ATM cell header structure 4 bits 3 bits 1 bit 4 bits 3 bits 1 bit GFC VPI VPI VCI PT HEC NNI structure CLP VPI VCI PT HEC UNI structure CLP! GFC = Generic Flow Control Bit! VPI = Virtual Path Identifier! VCI = virtual Circuit Identifier! PT = Payload Type! CLP = Cell Loss Priority! HEC = (CRC) Header Error Control

34 ATM - connections! Connection is always established between endpoints before sending data called virtual channels (unique on link).! Virtual paths aggregate virtual channels to scale up switching. Enables the creation of logical links between nodes.

35 ATM Adaptation Layers! ATM AALs are used to map different types of data onto ATM cells. Thus main function is segmentation and reassembly (SAR).! There are four different AALs: AAL1 for CBR (audio/video, BISDN- Class A), AAL2 for realtime VBR (VBR synchronous encoded audio/video, BISDN- Class B), AAL3/4 for (asynchronous connectionless and connection oriented VBR, BISDN- Class C ) and AAL5 for lightweight VBR (connectionless, asynchronous, IP packets, BISDN- Class D)

36 AAL - 1! Constant bit-rate synchronous traffic, e.g. telephony. Payload is 47 bytes, since 1 byte is used as an AAL-1 header containing a sequence number. This header is secured by a 4 bit CRC but not the payload.

37 AAL-5! To transmit asynchronous packets with sizes up to 64KB. This is the adaptation later used for IP datagrams. No additional overhead but uses the payload type field in the header for last cell indication. The last cell has 2 bytes of trailer containing CRC and length of packet.

38 ATM QoS! Traffic Shaping: contract for data flows is required between user and network (e.g., average, peak cell rate and average cell duration). If traffic violates this contract it can be dropped or labelled for dropping (CLP bit).! Admission Control: based on the ongoing contracts the network can determine (using sophisticated mathematics), what new connections it can admit to the system.! Queuing Techniques: used to monitor traffic and validate service contracts.! Flow control for UBR: if network is congested UBR traffic should be put on hold.

39 ATM Management! VPI and VCI are used to route cells but routing protocols are needed to determine what route should be taken to begin with.! Routing protocols: PNNI (private network to network interface) and B- ICI (broadband inter-carrier interface) are standardized by ATM-Forum.

40 ATM PNNI Routing! A switch maintains specific information on all outgoing links (e.g., cell loss, maximum cell delay, available bandwidth, administrative cost, weight).! These parameters are flooded to all other switches in the network, so ingress switches can calculate route that satisfies QoS requirements.! Once a route is computed, switches on the route are informed and VPI and VCI are assigned. (Tear down signalling is also needed)

41 IP (Internet Protocol)

42 IP! IP is designed to work over almost any data-link/physical layer. telnet, ftp, rlogin, SNMP TCP, UDP IP Ethernet, Token ring, PPP, HDLC Coaxial/twisted pair cable Optical layer SONET layer Applications Transport layer Network layer Data link layer Physical layer

43 IP over WDM! IP can be supported in several different ways over WDM. IP IP IP ATM SONET PPP SONET Ethernet MAC Ethernet PHY Optical (WDM) Optical (WDM) Optical (WDM) IP o. ATM o. SONET Packet over SONET Ethernet over WDM! IP does not guarantee in-sequence delivery, thus the need for TCP (and UDP).