Index

Next: List of Acronyms Up: Survey of Multicast Support Previous: List of Figures

Index

AAL5: ATM Adaptation Layers, Classical IP and ARP
abstraction: Network Interface Layer
address: Internet Layer
Address Resolution Protocol: Motivation to research IP , Network Interface Layer, ARP
address space: Internet Layer, IP addressing
algorithm: Multicast Address Resolution
algorithmic relation: ARP
ANS: Other supported features:
Any-cast: Signalling UNI
Application Protocols: Application Protocols
Applications protocols: Application Layer
architectural views: Interconnection of Nodes in
aread: ATM Hardware for Linux
Arequipa: Other supported features:
ARP cache: ARP on a Broadcast
ARP entity: ARP on a LAN
ARPANET: The Internet Protocol Suite
Asynchronous Transfer Mode: Introduction, ATMLANE and CLIP
ATM: Introduction, The Internet Protocol Suite, Implementation Architecture of Physical , Data Forwarding between IP , RFC 2022 Concepts
ATM Adaptation Layers: ATM Adaptation Layers
ATM as Network Interface: ARP on a non-broadcast
ATM Bearer Service: ATM Bearer Service, LAN Emulation (LANE)
ATM Cells: Physical Layer, Virtual Connections
ATM Forum: Original Problem Statement, LAN Emulation (LANE)
ATM hosts: Network Structure
ATM level: ATM Adaptation Layers
ATM networks: Asynchronous Transfer Mode (ATM)
ATM over TCP: The following Physical Interface
ATM protocol stack: Basic Concepts
ATM provider: VC Mesh
ATM signalling protocols: UNI 3.1 or 4.0 Multicast
ATM switch: VC Mesh
ATM switches: Network Structure
ATM-switch: Connecting the Hardware
ATMARP: Internal Structure of the
ATMARP daemon: Internal Structure of the
ATMARP server: ARP on a non-broadcast , Classical IP and ARP , RFC 2022 Concepts
ATMARPd: Internal Structure of the
ATMSIGd: Internal Structure of the
Authority and Format Identifier: Native ATM addresses
Available Bit-Rate: ATM Transport Layer
awrite: ATM Hardware for Linux
B-ISDN: Asynchronous Transfer Mode (ATM)
back-to-back: Connecting the Hardware
bandwidth: Introduction
Bellcore: Available Source Code
black box: Network View in the
bottleneck: Pros and Cons of
broadcast: Motivation to research IP , Network Interface Layer, IP addressing, ARP on a non-broadcast , Data Forwarding between IP
Broadcast and Unknown Server: Original Problem Statement, LANE Architecture
broadcast LAN: ARP on a LAN, ARP on a Broadcast
broadcasting: IP router
BSD socket API: BSD Socket API
BUS: LANE Architecture, Available Source Code
bypass cluster-boundaries: Comments on EARTH and
C programming language: Time scale of an
cables: Physical Layer
CBR: ATM Transport Layer
Cell: ATM Transport Layer
Cell Delay: ATM Transport Layer
Cell Delay Variation: ATM Transport Layer
Cell-Loss Ratio: ATM Transport Layer
class: IP addressing
Class D: Multicasting, Periodic Host Membership Queries, RFC 2022 Concepts, Multicast Address Resolution
Classical IP and ARP over ATM: Motivation to research IP , ARP on a non-broadcast , Classical IP and ARP , Multicast Address Resolution
client-part: Application Layer
CLIP: IP Multicast Transmission Example, Integration of the MARS , Internal Structure of the , Configuration of Classical IP
CLIP code: MARS Cluster Member
cloud: Network View, Network View in the
cluster boundaries: LLC/SNAP encapsulation
Cluster Member Identifier: MARS Group Management
cluster members: MARS Group Management
ClusterControlVC: MARS Group Management, MARS Server
CMI: Discussion of the multicast
collisions: LAN Emulation (LANE)
communicating virtually: Protocol Stack View
component: Network View
conferencing: Introduction, IP Multicast Usage
connection oriented: Basic Concepts
connection table: Pros and Cons of
connectionless traffic: ATM Adaptation Layers
connectionless traffic over ATM: Virtual Connections
connectors: Physical Layer
Constant Bit-Rate: ATM Transport Layer
control plane: Protocol Entities in the , VC Mesh
copy service: Discussion, Copy Service Implementation Choices, Available Source Code
copying entity: Discussion
cross-connect tables: Virtual Connections
CSMA-CD: LAN Emulation (LANE)
Data Country Codes: Native ATM addresses
Datacom: Asynchronous Transfer Mode (ATM)
Definition of Multicasting: Multicasting
device driver: Internal Structure of the
Device drivers: Kernel-space vs. User-space
devices: Network View in the
discard reflected: LLC/SNAP encapsulation
distributed protocol stack view: Network View, Network View in the
distributed view: IP Multicast Transmission Example
Domain Specific Part: Native ATM addresses
E.164: Native ATM addresses
EARTH: IP Multicast over ATM
ELAN: LANE Architecture
Emulated LAN: LANE Architecture
encapsulation: Classical IP and ARP
End-System Identifier: Native ATM addresses
endpoint: Internet Layer
Ethernet: Motivation to research IP , The Internet Protocol Suite, ARP, ARP on a Broadcast , ATMLANE and CLIP, LAN Emulation (LANE), IP Multicasting over ATM, Internal Structure of the
Ethernet ARP: Classical IP and ARP
Ethernet MAC address: Native ATM addresses
example implementation: Available Source Code
FDDI: Asynchronous Transfer Mode (ATM)
FIFO: VC Mesh
forwarding: IP multicasting
functionality: IETF Layer Functions, Implementation Architecture of Physical
functions: IETF Layer Functions
GNU General Public License: The Linux Operating System
group membership: IP multicasting
HELLO messages: Multicast Server
High Order DSP: Native ATM addresses
host: NodesHosts and Routers
host group: Periodic Host Membership Queries, VC Mesh, Multicast Server
host group address: Adding multicast support to
host group changes: Comparison between the VC-mesh
host group memberships: Pros and Cons of
host ID: Resolution for non-local IP
Host Membership Query: Periodic Host Membership Queries
Hosts: Network View in the
HTML: Structure of This Thesis
human;tex2html_html_special_mark_quot;analogue: Protocol Stack View
IANA: IP addressing
ICMP: Internet Layer
IEEE 802.3: LAN Emulation (LANE)
IEEE 802.5: LAN Emulation (LANE)
IETF: Original Problem Statement, IETF Protocol Stack, The Multicast Backbone (MBone), Classical IP and ARP
IGMP: Internet Layer, Adding multicast support to , IGMP in combination with
IGMP functions: IGMP to MARS interface
IGMP queries: IGMP in combination with
IGMP reports: Periodic Host Membership Queries, IGMP in combination with
IGMP_Leave: Leaving a Host Group
IGMP_QUERY: Leaving a Host Group, IGMP to MARS interface
ILMId: Internal Structure of the
implementation: TCP/IP Protocol Suite Implementation
InARP: ATMARP and InATMARP
InATMARP: Classical IP and ARP
Information Elements: ATM Transport Layer
Initial Domain Identifier: Native ATM addresses
inter-cluster multicast: VENUS
interconnecting network: Implementation Architecture of Physical
interface: ARP
Interim Local Management Interface: Native ATM addresses
International Code Designator: Native ATM addresses
Internet: Structure of This Thesis, IP addressing, Interconnection of Nodes in , The Multicast Backbone (MBone)
Internet Control Message Protocol: Internet Layer
Internet Group Management Protocol: Internet Layer
Internet Protocol: Motivation to research IP , The Internet Protocol Suite, Internet Layer, IP multicasting
interpreting: Protocol Stack View
intra-cluster: IP Multicast Transmission Example
ION: VENUS
IP: The Internet Protocol Suite
IP address: Resolution for non-local IP
IP host: IP router
IP multicast: RFC 2022 Concepts
IP multicasting: Implementation Architecture of Physical , Data Forwarding between IP
IP router: Network View in the , IP addressing, ARP on a LAN, IP router
IP routing: Virtual Connections
IP service provider: Network View in the
IP;tex2html_html_special_mark_quot;layer: Network View in the
IPv6: IP multicasting, The Multicast Backbone (MBone), Conclusions, Integration into the Next
IPX: Carrying Connectionless Data over
ISDN: Native ATM addresses
JoinLocalGroup: MARS Group Management
kernel: Getting ATM operational
kernel-space: Kernel-space vs. User-space
LAN: Network View in the
LAN address: Network Interface Layer
LAN clouds: Interconnection of Nodes in
LAN Emulation: Motivation to research IP , LAN Emulation (LANE), Other supported features:
LAN Emulation Configuration Server: LANE Architecture
LAN Emulation Server: LANE Architecture
LAN multicast: IGMP to MARS interface
LAN service provider: LANE Architecture
LANE: IP Multicasting over ATM
LANE Clients: LANE Architecture
LANE multicast: Conclusions
LANE User-Network Interface: LANE Architecture
layers: Protocol Stack View
Leaf Initiated Join: Signalling UNI
LeaveLocalGroup: MARS Group Management
levels of multicast support: Adding multicast support to
licenses: The Linux Operating System
Linux kernel: Future Developments of the
Linux operating system: Linux ATM System
Linux-ATM: Comparison between the VC-mesh , Linux ATM System, Internal Structure of the
Linux-ATM package: Currently Supported Features
LIS: ARP on a non-broadcast , Classical IP and ARP
LLC/SNAP: Classical IP and ARP , IP Multicast Transmission Example
LLC/SNAP encapsulation: IP Multicast Transmission Example, Internal Structure of the
LLC/SNAP;tex2html_html_special_mark_quot;encapsulation: Carrying Connectionless Data over
Local Area Network: The Internet Protocol Suite
Logical IP Subnet: ARP on a non-broadcast , Classical IP and ARP , RFC 2022 Concepts
loop-back: Connecting the Hardware
MAC addresses: LANE Architecture
MARP: MARS Server
MARS: RFC 2022 Concepts
MARS Cluster: Multicast Address Resolution
MARS Cluster member: MARS Cluster Member
MARS server: RFC 2022 Concepts
MARS-Cluster: RFC 2022 Concepts
MARS_GROUPLIST_REPLY: IGMP in combination with
MARS_GROUPLIST_REQUEST: IGMP in combination with
MARS_MULTI: Multicast Address Resolution
MARS_NAK: Multicast Address Resolution
MARS_REQUEST: Multicast Address Resolution
MARSport: Available Source Code
Maximum Burst Size: ATM Transport Layer
Maximum Transmission Unit: IP Multicasting over ATM
Maximum Transmit Unit: Classical IP and ARP
MBone: IP Multicast Usage
MCS implementation: Association with an IP
membership information: MARS Server
mIP/ATM: LANE Architecture, Conclusions, IP Multicast Transmission Example
mrouter: Adding multicast support to , The Multicast Backbone (MBone), IGMP to MARS interface
multicast: Network Interface Layer, Internet Layer
Multicast address resolution: Adding multicast support to
Multicast Address Resolution Server: RFC 2022 Concepts
Multicast applications: IP Multicast Usage
multicast LAN address: Adding multicast support to
multicast router: Multicasting, Basic IGMP operations, IGMP in combination with
multicast routers: IP Multicast Transmission Example, IP Multicast Transmission Example
Multicast Server: Signalling UNI, LANE Architecture, RFC 2022 Concepts
multicast traffic: Internet Group Management Protocol
multicast transmission: Pros and Cons of
multicast transmissions: Adding multicast support to
multicast tree: Pros and Cons of
multicasting: Introduction, TCP/IP Protocol Suite Implementation , IP router, IP multicasting
multimedia: IP Multicast Usage
multiple unicast: Multicasting
multipoint-to-multipoint: Signalling UNI, Intra-Cluster IP Multicast Transmissions
NASA: The Multicast Backbone (MBone)
NBMA: Next Hop Resolution Protocol
Netherlands: Native ATM addresses
network cloud: Network View
network description: Structure of This Thesis
network ID: Resolution for non-local IP
Network Identifier: Native ATM addresses
Network Information Service: Motivation to research IP
Network Interface: ARP
network interface layer: Network View in the
Network Service Access Point: Native ATM addresses
network technologies: The Internet Protocol Suite
Network View: Basic Network Description, Network View
Next Hop Resolution Protocol: Next Hop Resolution Protocol
NFS: Conclusions
NHRP: Next Hop Resolution Protocol
NICStAR: Linux ATM System
node: NodesHosts and Routers
nodes: Protocol Stack View, Network View in the
non-broadcast LAN: ARP on a LAN
Non-Broadcast Multi-Access: Next Hop Resolution Protocol
Operating Systems Design: Kernel-space vs. User-space
OSI: IETF Protocol Stack, Native ATM addresses
P-NNI: Network Structure
packets: Internet Layer
Payload: ATM Transport Layer, Classical IP and ARP
Peak Cell Rate: ATM Transport Layer
peer protocol;tex2html_html_special_mark_quot;entities: Protocol Entities in the
Permanent Virtual Connection: ATM Signalling Entities
Physical Layer: Network View in the , Basic Concepts
physical networks: The Internet Protocol Suite
point of interaction: Network View in the
point-to-multipoint: Signalling UNI, IP Multicasting over ATM, Intra-Cluster IP Multicast Transmissions , Discussion of the multicast
point-to-multipoint VCC: LANE Architecture
port numbers: Transport Layer
port-numbers: IP addressing
Private Network: Network Structure
Private UNI: Network Structure
production environment: Motivation to research IP
protocol entities: TCP/IP Protocol Suite Implementation , Implementation Architecture of Physical , IP Multicast Transmission Example
protocol handling function: TCP/IP Protocol Suite Implementation
protocol stack: LAN Emulation (LANE), IP Multicast Transmission Example, Internal Structure of the
protocol stack view: Basic Network Description
Public Network: Network Structure
PVPC: Virtual Connections
QoS: Network Interface Layer, ATM Transport Layer
Quality of Service: Network Interface Layer, Asynchronous Transfer Mode (ATM)
querying: Internet Group Management Protocol
radio: The Internet Protocol Suite
Re-assembly: ATM Adaptation Layers
redundancy for the MCS: Multicast Server
reference models: IETF Protocol Stack
references: Structure of This Thesis
reflected packets: VC Mesh, Pros and Cons of
reflected transmission: Discussion of the multicast
reliable service: Transport Layer
reliable transport protocol: IP Multicast Usage
Request For Comment: Introduction
resolve Class D addresses: MARS Cluster Member
Reverse ARP: Network Interface Layer
RFC: Introduction
RFC 1112: RFC 2022 Concepts
RFC 1577: Problem statement, Classical IP and ARP
RFC 1626: Classical IP and ARP
RFC 1755: Classical IP and ARP
RFC 2022: Original Problem Statement, IP Multicasting over ATM
RFC 2149: Multicast Server
RFC 1483: Classical IP and ARP
root: Signalling UNI, Intra-Cluster IP Multicast Transmissions
router: NodesHosts and Routers
routers: Network View in the
routing: Internet Layer
SAAL: ATM Signalling Entities
SAP: Network View in the
satellites: The Internet Protocol Suite
SCSP: EARTH
SDH: Physical Layer
SDU: Packet Encapsulation
Segmentation: ATM Adaptation Layers
SEL: Native ATM addresses
selector byte: Native ATM addresses, RFC 2022 Concepts
server-part: Application Layer
ServerControlVC: MARS Group Management, MARS Server
Service Access Point: Network View in the
Service Category: ATM Transport Layer
Service Data Unit: Packet Encapsulation
Service Provider: Protocol Stack View, Network View in the
Service User: Protocol Stack View, Network View in the
services: Protocol Stack View
signalling: Virtual Connections, The following connection types
Signalling ATM Adaptation Layer: ATM Signalling Entities
signalling daemon: Getting ATM operational
signalling overhead: VC Mesh
simultaneous multiple sends: Pros and Cons of
single point of failure: VC Mesh, Pros and Cons of
socket: BSD Socket API
Solaris: Linux ATM System
Solaris/Sparc implementation: Time scale of an
SONET: Physical Layer
statistical multiplexing: ATM Transport Layer
subscriptions to host group: Adding multicast support to
subset of the UNI 3.1: UNI 3.1 or 4.0 Multicast
Sustainable Cell Rate: ATM Transport Layer
Switched Virtual Connections: ATM Signalling Entities
Synchronous Digital Hierarchy: Physical Layer
Synchronous Optical NETwork: Physical Layer
TCP: The Internet Protocol Suite, Transport Protocols
TCP/IP: TCP/IP Protocol Suite Implementation
TCP/IP implementation model: ARP on a LAN
TCP/IP protocol suite: The Internet Protocol Suite
Telecom: Asynchronous Transfer Mode (ATM)
telephone companies: Asynchronous Transfer Mode (ATM)
telephone networks: Basic Concepts
telephone-wires: The Internet Protocol Suite
temporary connections: Pros and Cons of
temporary solution: UNI 3.1 or 4.0 Multicast
three issues: RFC 2022 Concepts
timing relation: ATM Adaptation Layers
Token-Ring: ATMLANE and CLIP, LAN Emulation (LANE)
traffic contract: ATM Transport Layer
Traffic Descriptor: ATM Transport Layer
Transfer Mode: ATM Transport Layer
Transmission Control Protocol: The Internet Protocol Suite, Transport Protocols
transmitting: Protocol Stack View
Transport layer: Transport Layer
Transport Protocols: Transport Protocols
tunnelling: Adding multicast support to
tunnels: The Multicast Backbone (MBone)
UDP: Transport Protocols
UNI 3.1: Signalling UNI, Intra-Cluster IP Multicast Transmissions , Supposed Point-to-Multipoint SVC Support
UNI 4.0: Signalling UNI
unicast: Network Interface Layer, ARP on a non-broadcast
unidirectional VCCs: Signalling UNI
Universal Resource Locators: Structure of This Thesis
University of Twente: Motivation to research IP , Native ATM addresses
Unix: The Linux Operating System
UNI 4.0: UNI 3.1 or 4.0 Multicast
Unshielded Twisted Pair: Physical Layer
Unspecified Bit-Rate: ATM Transport Layer
upper protocol layers: Network View in the , IP Multicast Transmission Example
URL: Structure of This Thesis
User Datagram Protocol: Transport Protocols
user-space: Kernel-space vs. User-space
user;tex2html_html_special_mark_quot;plane: Protocol Entities in the
Variable Bit-Rate: ATM Transport Layer
VC multiplexing: Classical IP and ARP
VC-mesh: RFC 2022 Concepts
VCC: Virtual Connections
VCI: ATM Transport Layer
VCL: Virtual Connections
VC multiplexing: Carrying Connectionless Data over
VENUS: IP Multicast over ATM
Virtual Channel Connection: ATM Adaptation Layers
Virtual Channel Identifier: ATM Transport Layer
Virtual Channel Link: Virtual Connections
Virtual Path Identifier: ATM Transport Layer
Virtual Path Link: Virtual Connections
VPI: ATM Transport Layer
VPI/VCI pair: Conclusions
web-sites: Structure of This Thesis
World Wide Web: Introduction
WWW: Introduction
X.25: Next Hop Resolution Protocol

Simon Oosthoek
Wed Jul 9 20:08:23 CEST 1997