Home

News White Papers

Buyer's Guide


 
 

 

Transport of Next-Generation Data Services over SDH


Training Course Outline

Course Duration:
3 days

Training Course Description:
Next generation networks will be deployed with high speed, high quality broadband DSL access capable of using flexible coding techniques. Multi-Service Access Nodes will carry services to Intelligent Nodes closer to the core where services will be located and then on to the network core using MPLS. The access is likely eventually to evolve into an all Ethernet service and the range of services carriers must deliver will need to be carried over existing SDH services. This course aims to provide an understanding of how these new services can be carried over SDH and how SDH is being enhanced to provide new capabilities to deliver the services in a flexible efficient manner.

When you have completed this course you will be able to:
  • Describe how access services are evolving
  • Compare existing SDH transports with new evolving Next Generation SDH
  • MAP Access services to SDH with GFP
  • Employ Virtual Containers in the Transport
  • Utilize for efficient service deployment
  • Enhance switching technologies to interface to GMPLS core services
  • Deploy mechanisms to deliver End to End QoS for applications

Prerequisites:
It will be assumed that attendees will already have a knowledge of 21st Century Networks such as that obtained from courses in Multi Service Access.

Prerequisite courses:
Understanding MultiService Access and H.248
Understanding MultiService Access and SIP

Transport of Next-Generation Data Services over SDH includes the following modules:

Next generation Architecture

  • Why do we need Next Generation Networks?
  • Next Generation Service Demands
  • Access Speed Growth
  • Digital Subscriber Loop Services
  • Distance Speed Tradeoff
  • Multi Service Access
  • Metro Node Services
  • Core Services
  • Service Profiles
  • Management Control
  • Next Generation Access Services
  • User Service Interfaces
  • DSL Options
  • ADSL, ADSL-2+ and VDSL
  • DSL protocol Stacks
  • Ethernet Access Services

SDH Structure and Architecture

  • Evolution of Synchronous Optical Network (SONET)
  • STS, OC and STM Hierarchy
  • SDH Frames and Architectures
  • Header Overhead
  • Payload Envelopes
  • Virtual Containers
  • Multiplexing Structure
  • TUGs and VCs
  • Example carriage of E1 over VC12
  • Pointer Regeneration
  • Clock Transparency
  • Monitoring and Performance
  • Next Generation Service Mapping
  • Contiguous Concatenation
  • Virtual Concatenation
  • Bandwidth management
  • Virtual Container Transport
  • Mapping in Frames

Mapping Access Services to SDH Using Generic Framing Procedure (GFP)

  • G.7041/Y.1303
  • Purpose of GFP
  • Frame Mapped GFP (GFP-F)
  • Transparent GFP (GFP-T)
  • Relationship between Client and Transport Signals
  • Framing for User Frames
  • Payload Header
  • Type Field
  • GFP Control Frames
  • Frame Delineation
  • Example PPP Encapsulation
  • Error Handling
  • Transport Mapping for Low Latency Signals
  • Gigabit Ethernet Payloads
  • Other Payload Types

Virtual Concatenation (VCAS) for Using Bandwidth Efficiently

  • Virtual Concatenation (VCAT) G.707
  • VC Types
  • Contiguous Concatenation Types
  • Contiguous and Virtual Concatenation efficiency
  • virtual concatenation using VC-3-6v
  • H4 and K4 codification of Multiframes
  • H4 codification for VCAT Multiframes

Link Capacity Adjustment Scheme G.7042

  • Purpose of LCAS
  • Bandwidth Allocation
  • Diversification Strategies
  • Asymmetric Configurations
  • LCAS Protocol
  • H4 and K4 byte contents
  • LCAS States
  • Example LCAS exchange
  • Using LCAS for connecting GbE between Sites
  • Sink and Source Messages
  • Interaction between VCAT and LCAS

Generalized Multi-Protocol Label Switching (GMPLS)

  • RFC 3471 and 4328
  • G.709
  • Functions of MPLS
  • Label Distribution Protocol
  • Forward Equivalence Classes
  • Generalized Label Request
  • Generalized PID (G-PID)
  • Bandwidth Encoding
  • Generalized Label
  • Label Set Information
  • Label Contention Resolution
  • Explicit Label Control
  • Fault Handling
  • Signalling extensions for G.709
  • Traffic Parameters
  • Label Distribution Rules
  • Optical Channel Label Space
  • RSVP-TE Signaling Protocol Extensions
  • CR-LDP Extensions RFC 3472
  • Format of Generalized Label
  • Label Set for CR-LDP
  • Interface Ids
  • Routing Extensions in support of GMPLS RFC 4202
  • ISIS-TE and OSPF-TE

End to End Quality of Service

  • Comparision between QoS approaches as Layers 2 and 3
  • Using DiffServ for End to End QoS
  • IP TOS Byte
  • IntServ, Its Strengths and Shortcomings
  • The Differentiated Services Architecture
  • Packet Marking
  • Per Hop Behaviors
  • The Default PHB (Defined in RFC-2474)
  • Class-Selector PHBs
  • Expedited Forwarding PHB (Defined in RFC-2598)
  • Assured Forwarding PHB (Defined in RFC-2597)
  • Delivering E2E QoS over Next Generation Networks
  • Mapping traffic at the access
  • Hierarchical QOS Management
  • Ingress and Egress Considerations
  • Maintaining QoS in the event of failure in the core
  • Fast Reroute

Services over Ethernet Optical Networks

  • Carrier Ethernet
  • Triple Play over Metro Ethernet
  • Ethernet Private Line
  • Carrier Level Specifications
  • Architecture framework
  • Ethernet Layer Specifications
  • Service Definition
  • Service Attributes
  • UNI
  • Transport Multiplex Function
  • Circuit Emulation Service over Ethernet (CESoE)
  • Ethernet Virtual Circuits

Next Generation Application Services

  • Revenue Sectors
  • Home Entertainment
  • Internet Broadcasting
  • Security, Control and Telemetry
  • Streaming Services
  • Local TV
  • Domestic Internet Conferencing

View Course Schedule
 
Request Info/Contact
 
 

Home

 White Papers Equipment News

Trade Shows

 Billing Solutions Vendors Test Tools
Training

Advertising

 Contact Us

copyright 2007, Triple Play News, all rights reserved worldwide