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Advances in Optical Networks: SONET By Sean Goggin April 19, 2005 Overview • • • • Fundamentals of Optical Networks SONET SDH Future of SONET Tuesday, April 19, 2005 Advances in Optical Networks: SONET 2 Fundamentals of Optical Networks • • • • • Fiber Optic Medium Variants of Fiber and Optical Networks Multiplexing Methods Optical Network Equipment Topologies of Optical Networks Tuesday, April 19, 2005 Advances in Optical Networks: SONET 3 Fiber Optic Medium • Core – Medium Where Light Travels • Cladding – Reflects Light Back into the Core • Buffer Coating – Protective Coating Tuesday, April 19, 2005 Advances in Optical Networks: SONET 4 Variants of Fiber Optic • Single-Mode – Small Core Approximately 9 Microns – Uses IR Laser Light Transmitter – Greater then 10 Miles* – Most Expensive Tuesday, April 19, 2005 • Multi-Mode – Large Core Approximately 62.5 Microns – Uses Light Emitting Diode Transmitter – Less then 10 Miles* – Least Expensive *Without Regeneration Advances in Optical Networks: SONET 5 Types of Multiplexing • Time Division Multiplexing (TDM) – Simplest Implementation – Uses Single Wavelength • Wavelength Division Multiplexing (WDM) – Complex Implementation – Multiple Wavelengths on a Single Fiber to Increase Bandwidth Tuesday, April 19, 2005 Advances in Optical Networks: SONET 6 Types of Optical Networks • Opaque – Weak Signals are Boosted with a Repeater – Optical-ElectronicOptical (OEO) Repeater – Incurs Pricey Conversion Delay Tuesday, April 19, 2005 • All-Optical (Pure) – Weak Signals are Boosted with a Amplifier – Erbium-Doped Fiber Amplifier (EDFA) – Complete Photonic Boost Advances in Optical Networks: SONET 7 OEO Repeater Processor Strong Optical Signal Optical Transceiver Optical Transceiver Weak Optical Signal Electronic Circuit Pathway Tuesday, April 19, 2005 Advances in Optical Networks: SONET 8 Erbium Doped Fiber Amplifier Pump Laser Strong Optical Signal Filter Tuesday, April 19, 2005 ErbiumDoped Fiber Advances in Optical Networks: SONET Coupler Weak Optical Signal 9 Optical Network Equipment • Repeaters (OEO) & Amplifiers (EDFA) • Optical Crossconnects (OXC) – Photonic Switch with N Full-Duplex Ports • Optical Add-Drop Multiplexer (OADM) – Wavelengths Can Be Added and Removed from the Photonic Flow – Ex: Remove Traffic for Inbound T1 and Traffic for Outbound T1 – Needed for WDM Tuesday, April 19, 2005 Advances in Optical Networks: SONET 10 Optical Add-Drop Multiplexer Tuesday, April 19, 2005 Advances in Optical Networks: SONET 11 Topologies • Ring Topology – Data Moves in One Direction around 1st Ring – If Failure Occurs, Traffic is Rerouted in Opposite Direction on 2nd Ring – Each Ring is ½ Total Capacity – Self-Maintaining • Mesh Topology – Locations are Linked to 2 or More Other Locations – If a Link Fails, Traffic is Rerouted around the Failure – Requires Routes to be Established Before Failure Tuesday, April 19, 2005 Advances in Optical Networks: SONET 12 Ring Topology Internet Tuesday, April 19, 2005 Advances in Optical Networks: SONET 13 Mesh Topology Tuesday, April 19, 2005 Advances in Optical Networks: SONET 14 Sample of Optical Network Tuesday, April 19, 2005 Advances in Optical Networks: SONET 15 Telecom Terminology • • • • • Synchronous Optical Network (SONET) Asynchronous Transfer Mode (ATM) Digital Signal (DS) Synchronous Transport Signal (STS) Optical Carrier (OC) Tuesday, April 19, 2005 Advances in Optical Networks: SONET 16 Telecom Circuits • Digital Signal Levels – DS-0: 64 Kb Transmission Channel – DS-1(T1): 1.5 Mb; Formed of 24 DS-0 – DS-3(T3): 44.7 Mb; Formed of 672 DS-0 • Synchronous Transport Signals Channels – STS-1: 52 Mb; Formed of 28 DS-0 or a Single DS-3 – STS-3: 155 Mb; Formed of 84 DS-0 or 3 DS-1 – Electric Signal is Converted to an Optical Signal it Becomes OC Tuesday, April 19, 2005 Advances in Optical Networks: SONET 17 SONET Connections Megabits OC STS SONET Channels Per Second Level Level DS-1 DS-3 52 OC-1 STS-1 28 1 155 OC-3 STS-3 84 3 622 OC-12 STS-12 336 12 2,488 OC-48 STS-48 1,344 48 9,953 OC-192 STS-192 5,376 192 39,812 OC-768 STS-768 21,504 768 Tuesday, April 19, 2005 Advances in Optical Networks: SONET 18 Background of SONET • Conceived by MCI During the Mid-1980’s • Designed from the Ground-Up to Hasten the Adoption of Optical Technology • Capacity and Distance Increased Rapidly Due to Technological Developments – Increased Purity of Fiber Optic Cable • Longer Distance without Regeneration • Iron, Nickel, and Hydroxyl Ions Cause Impurities • 1970’s 20dB/km Loss, Today .2 dB/km Loss Tuesday, April 19, 2005 Advances in Optical Networks: SONET 19 – Development of Laser Technology • Lasers Yield Higher Energy then LEDs Allowing for Longer Distance Before Regeneration – Development of Pure-Optical Technology • Eliminating Optical-Electronic-Optical Conversion for Regeneration & Routing Increase Speed • Possibility to Breach 10 Gb Barrier – Wave Division Multiplexing & Dense Wave Division Multiplexing • Using Multiple Wavelengths Capacity Can Be Increased Upwards of 92 Times the Capacity of a Single Wavelength Tuesday, April 19, 2005 Advances in Optical Networks: SONET 20 • ANSI Transmission Standard – United States – Canada – Korea – Taiwan – Hong Kong • SDH used in Rest of the World – Interoperable with SONET Tuesday, April 19, 2005 Advances in Optical Networks: SONET 21 Description • • • • Physical-Layer Standard Four-Layer Protocol Stack TDM Creates Synchronous Channels Multiplex Many Types of Traffic into Uniform Streams onto Fiber Optic Cabling • Used Primarily as Backbone for ATM Tuesday, April 19, 2005 Advances in Optical Networks: SONET 22 • Not Well Suited for Data Because of Native 64 kilobit “chunks” • Utilizes Ring Topology for Reliability • Low Maintenance do to Automatic Protection Switching (APS) • Operations, Provisioning, Monitoring and Maintenance Functions are Done Uniformly and Efficiently Tuesday, April 19, 2005 Advances in Optical Networks: SONET 23 • Typical SONET Ring is Single Wavelength Opaque Network (Circa 2000) • Entire Ring Must Operate at the Same Speed • Adding Capacity to Rings Takes a Long Time and Typically Constitute a New Ring Due to Convenience • Recent use of IP Over SONET Tuesday, April 19, 2005 Advances in Optical Networks: SONET 24 Four-Layers of SONET • Photonic: STS Electrical Data is Converted into OC Light Pulses and Vice Versa • Section: Operates between Optical repeaters, Helping to Transmit STS Frames • Line: Synchronizes and Multiplexes Multiple Streams into One Stream, Invokes APS When Required • Path: Used for End-to-end Communications and Control Tuesday, April 19, 2005 Advances in Optical Networks: SONET 25 STS-1 Frame • Section, Line, and Path Stack Layers are Overheard in the basic STS-1 Frame • Frame is comprised of 9 Rows by 90 Columns = 810 bytes • 1st 3 Columns of Each Row Addresses Section and Line Overhead (27-Bytes) • 4th Column of Each Row Addresses Path Overhead (9-Bytes) • 86 Columns are Payload (774-Bytes) Tuesday, April 19, 2005 Advances in Optical Networks: SONET 26 Tuesday, April 19, 2005 Advances in Optical Networks: SONET 27 Section Overhead • 9-Bytes • Supports – Performance Monitoring (STS-N Signal) – Local Orderwire – Data Communication Channels – Framing Tuesday, April 19, 2005 Advances in Optical Networks: SONET 28 Line Overhead • 18-Bytes • Supports – Locating the Payload in the Frame – Multiplexing or Concatenating Signals – Performance Monitoring – Automatic Protection Switching (APS) – Line Maintenance Tuesday, April 19, 2005 Advances in Optical Networks: SONET 29 Path Overhead • 9 Evenly Distributed Path Overhead Bytes per 125 Microseconds • Supports – Performance Monitoring of Payload – Signal Label – Path Status – Path Trace Tuesday, April 19, 2005 Advances in Optical Networks: SONET 30 SONET Virtual Tributaries • SONET is Capable of Accommodating Large and Small Capacities • STS-1 Frame Payload Can be SubDivided to Create Virtual Tributaries (VT) • Services Below DS3 are Transported via VTs in SONET • VTs are Multiplexed to Reach Capacity of STS Payload Tuesday, April 19, 2005 Advances in Optical Networks: SONET 31 SONET Multiplexing Hierarchy Tuesday, April 19, 2005 Advances in Optical Networks: SONET 32 ATM Over SONET • Data-Link Layer Standard • Voice Packets are Synchronous and Continuous, Data Packets are Asynchronous and Burst • ATM Dynamically Allocates “Cells” to Voice and Data on Synchronous and Continuous Connection • Provides Routing, Quality of Service (QoS), and Flexible Traffic Engineering Tuesday, April 19, 2005 Advances in Optical Networks: SONET 33 Tuesday, April 19, 2005 Advances in Optical Networks: SONET 34 ATM Cell • ATM Cell is 53-Bytes = 48-Bytes User Data + 5-Byte Header • Fixed-Size Cell is More Manageable and Easy to Hardware Route • Cell Header Contains Information Pertaining to the Cell’s Path, Priority, and Other Useful Information Tuesday, April 19, 2005 Advances in Optical Networks: SONET 35 ATM Cell Header • General Flow Control (GFC, 4-bit) – Used for Local Functions, i.e. Identifying Multiple Stations that Share an ATM Interface. Typically not Used, Set to a Default Value • Virtual Path Identifier (VPI, 8-bit) – Used with the VCI, to Identify Next Destination of a Cell as it Passes through a Series of Routers on the Way to the Destination • Virtual Channel Identifier (VCI, 16-bit) – Used with the VPI, to Identify Next Destination of a Cell as it Passes through a Series of Routers on the Way to the Destination Tuesday, April 19, 2005 Advances in Optical Networks: SONET 36 • Payload Type (PT, 3-bit) – First Bit Indicates Whether the Cell Contains User or Control Data. If Cell Contains User Data, the Second Bit Indicates Congestion, and the Third Bit Indicates Whether the Cell is the Last in a Series of Cells • Congestion Loss Priority (CLP, 1-bit) – Indicates Whether the Cell Should be Discarded if it Encounters Extreme Congestion as it Moves through the Network • Header Error Control (HEC, 8-bit) – Checksum Calculated Only on the Header Itself Tuesday, April 19, 2005 Advances in Optical Networks: SONET 37 ATM Header Tuesday, April 19, 2005 Advances in Optical Networks: SONET 38 Problems with ATM – “Cell Tax” 53-Byte ATM Cells are too Small for Most Data Traffic – Ex: Requires Two 53-Byte ATM Cells to Transfer the Smallest IP Data Packet (64Bytes) – 5-Byte Tax for Every 48-Bytes of Data for ATM vs. 1,500-Bytes with Minimal Overhead in Ethernet (Best Case) – IP over ATM losses 20% of SONET Rate Tuesday, April 19, 2005 Advances in Optical Networks: SONET 39 IP Over SONET • Transports IP Utilizing Point-to-Point Protocol (PPP) and High-level Data Link Control (HDLC) – PPP Provides Multi-Protocol Encapsulation, Error Control, and Link Initialization Control – HDLC Frames the PPP-Encapsulated IP Datagrams into the STS-1 Frame’s Payload • Requires STS-3c (3 Multiplexed STS-1) Tuesday, April 19, 2005 Advances in Optical Networks: SONET 40 Promising Future • WDM Allows ATM and IP to Coexist on SONET • Pure-IP Networks Adopting Rapidly – ISPs (AOL) – Carriers (Sprint, GTE, Level 3, Qwest) • Telephony Traffic Remains Static, IP Traffic Increasing 7% to 20% Per Month • Cheaper then ATM Tuesday, April 19, 2005 Advances in Optical Networks: SONET 41 Issues to be Addressed • Generating Traffic for STS-3 (155 Mbps) • PPP Establishes Direct Link – No Addressing Capabilities – No Routing Capabilities • PPP has No Flow Control – Additional Router Buffer Maybe Necessary • Multiple Links Need to Be Provisioned in Event of Link Failure Tuesday, April 19, 2005 Advances in Optical Networks: SONET 42 • Without ATM’s Layer-2 QoS, QoS Must be Added at Layer-3 – Multi-Protocol Label Switching (MPLS) Utilized for QoS, Processor Intensive? • HDLC Poor Scaling Hampers Connections Above OC-48 – Lucent Proposes Simplified Data Link (SDL) Tuesday, April 19, 2005 Advances in Optical Networks: SONET 43 SDH • Synchronous Digital Hierarchy (SDH) Published in 1989 by CCITT • Addressing Synchronization of ANSI and CCITT Standards, Establishing a World Standard • 32 64-kb Channels (E0) are Multiplexed into a 2 Mbps E1 Signal • 21 E1 are Multiplexed into a STM-0 (52 Mbps) Tuesday, April 19, 2005 Advances in Optical Networks: SONET 44 SONET vs. SDH • 1.5 Mbps DS1 vs. 2 Mbps E1 • 52 Mbps STS-1 vs. 155 Mbps STM-1 • Multiplexing Smaller Connections into Larger is Similar to SONET • SDH can Accommodate SONET By Changing SONET Signal from BitInterleaving to Byte-Interleaving. Tuesday, April 19, 2005 Advances in Optical Networks: SONET 45 SDH Connections Megabits SDH STM Per Second Level Level 52 SDH Channels E1 E4 STM-0 21 155 SDH-1 STM-1 63 1 622 SDH-4 STM-4 252 4 2,488 SDH-16 STM-16 1,008 16 9,953 SDH-64 STM-64 4,032 64 39,812 SDH-256 STM-256 16,128 256 Tuesday, April 19, 2005 Advances in Optical Networks: SONET 46 Connection Comparison Mbps OC Level STS Level SDH Level 52 OC-1 STS-1 155 OC-3 STS-3 SDH-1 622 1244 2488 4976 OC-12 OC-24 OC-48 OC-96 9953 OC-192 19906 OC-384 39812 OC-768 Tuesday, April 19, 2005 STM Level STM-0 STM-1 STS-12 STS-24 STS-48 STS-96 SDH-4 SDH-8 SDH-16 SDH-32 STM-4 STM-8 STM-16 STM-32 STS-192 STS-384 STS-768 SDH-64 SDH-128 SDH-256 STM-64 STM-128 STM-256 Advances in Optical Networks: SONET 47 Future of SONET • 10 Gb Barrier – OC-768 – Tunable Lasers • SONET and Metro Ethernet – Which is Best for MAN? • IP Over SONET vs. IP Over Fiber – Fiber Infrastructure without SONET Tuesday, April 19, 2005 Advances in Optical Networks: SONET 48 Tuesday, April 19, 2005 Advances in Optical Networks: SONET 49
