IEEE IP over Broadband Access in Support of Convergence

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IEEEIP over Broadband Access in Support of
Convergence
Global Standards Collaboration (GSC) 14

• Dr. W. Charlton Adams,
• President, IEEE Standards Association

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IP over Broadband Access

• IEEE 802
• .3av Optical Networking
• .11ad High thruput wireless connectivity for
  fixed, portable, and moving stations within a
  local area
• .16 Broadband wireless access
• .20 - Mobile broadband wireless access
• .22 Wireless regional area network employing TV
  whitespace frequency spectrum
• IEEE P1901 Broadband Over Power line Networks
• IEEE P 1903 Next Generation Service Overlay
  Network

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Passive Optical Networking 10GEPONFiber
OpticsIEEE 802.3av
Standard for Information TechnologyTelecommunicat
ions and Information Exchange Between
SystemsLocal and Metropolitan Area
NetworksSpecific Requirements Part 3 Carrier
Sense Multiple Access with Collision Detection
(CSMA/CD) Access Method and Physical Layer
Specifications Amendment Physical Layer
Specifications and Management Parameters for
10Gb/s Passive Optical Networks

• Scope The scope of this project is to amend IEEE
  Std 802.3 to add physical layer specifications
  and management parameters for symmetric and/or
  asymmetric operation at 10 Gb/s on
  point-to-multipoint passive optical networks.
• Purpose The purpose of this document is to
  significantly increase performance of
  point-to-multipoint architecture (Ethernet
  Passive Optical Network) to support emerging
  bandwidth-intensive services while considering
  equipment, operation, upgrade, and maintenance
  costs.

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IEEE 802.11
IEEE Standard for Information TechnologyTelecommu
nications and Information Exchange Between
SystemsLocal and Metropolitan Area
NetworksSpecific RequirementsPart 11 Wireless
LAN Medium Access Control (MAC) and Physical
Layer (PHY) Specifications

• Scope The scope of this standard is to define
  one medium access control (MAC) and several
  physical layer (PHY) specifications for wireless
  connectivity for fixed, portable, and moving
  stations (STAs) within a local area.
• Purpose The purpose of this standard is to
  provide wireless connectivity for fixed,
  portable, and moving stations within a local
  area. This standard also offers regulatory bodies
  a means of standardizing access to one or more
  frequency bands for the purpose of local area
  communication.

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Wireless Access Very High ThroughputIEEE 802.11ad
IEEE Standard for Information TechnologyTelecommu
nications and Information Exchange Between
SystemsLocal and Metropolitan Area
NetworksSpecific RequirementsPart 11 Wireless
LAN Medium Access Control (MAC) and Physical
Layer (PHY) SpecificationsAmendment
Enhancements for Very High Throughput in the 60
GHz Band

• Scope This amendment defines standardized
  modifications to both the 802.11 physical layers
  (PHY) and the 802.11 Medium Access Control Layer
  (MAC) to enable operation in the 60 GHz frequency
  band (typically 57-66 GHz) capable of very high
  throughput. The MAC and PHY specified in this
  amendment Enables a maximum
  throughput of at least 1 Gbps, as measured at the
  MAC data service access point (SAP) Enables
  fast session transfer between PHYs Maintains
  the 802.11 user experience Provides
  mechanisms that enable coexistence with other
  systems in the band including IEEE 802.15.3c
  systems
• Purpose The purpose of the amendment is to
  improve the 802.11 user experience by providing
  significantly higher throughput for local area
  networking.

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Broadband Wireless Access IEEE 802.16
IEEE Standard for Local and Metropolitan Area
Networks Part 16 Air Interface for
Broadband Wireless Access Systems

• Scope This standard specifies the air interface,
  including the medium access control layer (MAC)
  and physical layer (PHY), of combined fixed and
  mobile point-to-multipoint broadband wireless
  access (BWA) systems providing multiple services.
  The MAC is structured to support multiple PHY
  specifications, each suited to a particular
  operational environment.
• Purpose This standard enables rapid worldwide
  deployment of innovative, cost-effective, and
  interoperable multivendor broadband wireless
  access products, facilitates competition in
  broadband access by providing alternatives to
  wireline broadband access, encourages consistent
  worldwide spectrum allocation, and accelerates
  the commercialization of broadband wireless
  access systems.

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Mobile Broadband Access IEEE 802.20
IEEE Standard for Local and Metropolitan Area
Networks Part 20 Air Interface for
Mobile Broadband Wireless Access Systems
Supporting Vehicular MobilityPhysical and Media
Access Control Layer Specification

• Scope This standard specifies the physical and
  medium access control layers of an air interface
  for interoperable mobile broadband wireless
  access systems, operating in licensed bands below
  3.5 GHz. The system is optimized for IP-data
  transport, with peak data rates per user in
  excess of 1 Mbps.

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IP over Broadband Access IEEE 802.22
Draft Standard for Information TechnologyTelecomm
unications and information exchange between
systemsWireless Regional Area Networks
(WRAN)Specific requirementsPart 22 Cognitive
Wireless RAN Medium Access Control (MAC) and
Physical Layer (PHY) specifications Policies
procedures for operation in the TV Bands

• Scope This standard specifies the air interface,
  including the medium access control layer (MAC)
  and physical layer (PHY), of fixed point-to-
  multipoint wireless regional area networks
  operating in the VHF/UHF TV broadcast bands
  between 54 MHz and 862 MHz.
• Purpose This standard is intended to enable
  deployment of interoperable 802 multivendor
  wireless regional area network products, to
  facilitate competition in broadband access by
  providing alternatives to wireline broadband
  access and extending the deployability of such
  systems into diverse geographic areas, including
  sparsely populated rural areas, while preventing
  harmful interference to incumbent licensed
  services in the TV broadcast bands.

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Broadband over Power Line NetworksIEEE P1901

• Scope The project will develop a standard for
  high speed (gt100 Mbps at the physical layer)
  communication devices via alternating current
  electric power lines, so called Broadband over
  Power Line (BPL) devices. The standard will use
  trannsmission frequencies below 100 MHz. This
  standard will be usable by all classes of BPL
  devices, including BPL devices used for the
  first-mile/last-mile connection (lt1500m to the
  premise) to broadband services as well as BPL
  devices used in buildings for LANs and other data
  distribution (lt100m between devices). This
  standard will focus on the balanced and efficient
  use of the power line communications channel by
  all classes of BPL devices, defining detailed
  mechanisms for coexistence and interoperability
  between different BPL devices, and ensuring that
  desired bandwidth and quality of service may be
  delivered. The standard will address the
  necessary security questions to ensure the
  privacy of communications between users and allow
  the use of BPL for security sensitive services.
  This standard is limited to the physical layer
  and the medium access sub-layer of the data link
  layer, as defined by the International
  Organization for Standardization (ISO) Open
  Systems Interconnection (OSI) Basic Reference
  Model. The effort will begin with an architecture
  investigation, and this will form the basis for
  detailed scope of task groups that will work
  within P1901 to develop the components of the
  final standard.
• Purpose New modulation techniques offer the
  possibility to use the power lines for high speed
  communications. This new high speed media is
  open, and locally shared by several BPL devices.
  Without an independent, openly defined standard,
  BPL devices serving different applications will
  conflict with one another and provide
  unacceptable service to all parties. The standard
  will provide a minimum implementation subset
  which allows the fair coexistence of the BPL
  devices. The full implementation will provide the
  interoperability among the BPL devices, as well
  as interoperability with other networking
  protocols, such as bridging for seamless
  interconnection via 802.1. It is also the intent
  of this effort to quickly progress towards a
  robust standard so powerline applications may
  begin to impact the marketplace. The standard
  will also comply with EMC limits set by national
  regulators, so as to ensure successful
  coexsitence with wireless and telecommunications
  systems.

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Next Generation Service Overlay Network IEEE
P1903

• Scope Describes a framework of Internet
  Protocol(IP)-based service overlay networks and
  specifies context-aware, (e.g., such as required
  Quality of Service(QoS) level, type of service
  such as real-time vs. data, nature of data stream
  such as I-frame vs. B-frame, and type of terminal
  such as TV monitor vs. Personal Digital
  Assistant) dynamically adaptive (e.g., using
  locally derived information to discover,
  organize, and maintain traffic flows in the
  network within a local area network), and
  self-organizing networking capabilities (e.g.,
  developing network structures based on the needs
  of the customers and the capabilities of existing
  network structures), including advanced routing
  and forwarding schemes, and that are independent
  of underlying transport networks.
• Purpose To enable network operators,
  service/content providers, and end-users to
  provide and consume collaborative services by the
  deployment of context-aware, dynamically
  adaptive, and self-organizing networking
  capabilities.