This document provides an overview of networking protocols from 1999-2000, organized by the OSI model layers. It lists many protocols for physical, data link, network, transport, session, presentation and application layers. The protocols span technologies like TCP/IP, X.25, Frame Relay, ATM, SNA, AppleTalk, IPX, and cellular networks. The document serves as a reference for the purpose and relationships of various protocols.
RADCOM is a market leader in service assurance and customer experience management solutions. It has over 300 million subscribers using its solutions and serves network providers in 50 countries. RADCOM's Omni-Q solution provides full coverage monitoring of networks and services through various probes. Omni-Q enables performance monitoring, troubleshooting, and analysis across VoIP, NGN, IMS and other network types through applications like session tracing, subscriber search, and handset analysis. RADCOM offers a powerful, vendor-independent platform that can scale to meet various user needs.
The document provides information about intelligent networks and CAMEL protocol. It discusses why intelligent networks were developed by removing service creation from switches to a remote Service Control Point node. It then gives a brief history of intelligent networks and provides details on the basics of intelligent networks including the network elements, relationship between elements, basic call state models for originating and terminating calls, and detection points.
Xener provides comprehensive NGN solutions including softswitches, signaling gateways, network management systems, and media servers. Their solutions help telecom providers migrate from legacy networks to IP-based networks for lower costs, higher bandwidth, and new services. Xener's systems support nearly 5 million subscribers in Korea and their solutions power the daily services of 8 of 9 Internet telephony providers in Korea.
This document discusses IMS architecture and future developments:
1. It provides an overview of the IMS architecture, including network elements like CSCF, HSS, and application servers.
2. It discusses IMS standards and the migration path from Release 4 to Release 5. Future releases will enhance interworking, services, and access types.
3. IMS provides an IP-based control infrastructure for combining voice, video, and real-time multimedia services on a single network.
This document provides an overview of the IP Multimedia Subsystem (IMS) standards and architecture. It discusses the evolution from 2G to 3G/4G mobile networks and the integration of IMS. The key components of IMS are described including the Call Session Control Function (CSCF), Home Subscriber Server (HSS), Application Servers (AS), Media Resource Functions (MRF), and Breakout Gateway Control Function (BGCF). Registration and call flow examples are provided to illustrate IMS signaling. Approaches to migrating existing networks to IMS are also summarized.
The document summarizes the features of a cloud-based VoIP softswitch called HostedSwitch. It handles high call volumes with scalability and reliability. It allows for SIP and H.323 integration, codec conversion, and an API for integration. It also offers least cost routing, quality routing, time-based routing, ANI routing, and rerouting. The billing system provides real-time CDRs, flexible billing, profit analysis, and prepaid or postpaid customer billing. Analytics include real-time graphs, dashboards, reports, alerts, and activity logs. HostedSwitch has low upfront costs and allows rapid market entry with a complete VoIP solution and free software updates.
MVTS Pro is a high performance class 4 softswitch with SBC functionality - a carrier-grade solution for efficient VoIP traffic management and wholesale peering.
The document discusses various scenarios and uncertainties around next generation network architectures, including an increasingly fragmented network landscape with multiple providers involved in service delivery. It also summarizes challenges around ensuring quality of service and network resilience as networks transition to IP-based architectures and applications. Customer ownership and retaining control of the customer relationship is a key issue discussed.
RADCOM is a market leader in service assurance and customer experience management solutions. It has over 300 million subscribers using its solutions and serves network providers in 50 countries. RADCOM's Omni-Q solution provides full coverage monitoring of networks and services through various probes. Omni-Q enables performance monitoring, troubleshooting, and analysis across VoIP, NGN, IMS and other network types through applications like session tracing, subscriber search, and handset analysis. RADCOM offers a powerful, vendor-independent platform that can scale to meet various user needs.
The document provides information about intelligent networks and CAMEL protocol. It discusses why intelligent networks were developed by removing service creation from switches to a remote Service Control Point node. It then gives a brief history of intelligent networks and provides details on the basics of intelligent networks including the network elements, relationship between elements, basic call state models for originating and terminating calls, and detection points.
Xener provides comprehensive NGN solutions including softswitches, signaling gateways, network management systems, and media servers. Their solutions help telecom providers migrate from legacy networks to IP-based networks for lower costs, higher bandwidth, and new services. Xener's systems support nearly 5 million subscribers in Korea and their solutions power the daily services of 8 of 9 Internet telephony providers in Korea.
This document discusses IMS architecture and future developments:
1. It provides an overview of the IMS architecture, including network elements like CSCF, HSS, and application servers.
2. It discusses IMS standards and the migration path from Release 4 to Release 5. Future releases will enhance interworking, services, and access types.
3. IMS provides an IP-based control infrastructure for combining voice, video, and real-time multimedia services on a single network.
This document provides an overview of the IP Multimedia Subsystem (IMS) standards and architecture. It discusses the evolution from 2G to 3G/4G mobile networks and the integration of IMS. The key components of IMS are described including the Call Session Control Function (CSCF), Home Subscriber Server (HSS), Application Servers (AS), Media Resource Functions (MRF), and Breakout Gateway Control Function (BGCF). Registration and call flow examples are provided to illustrate IMS signaling. Approaches to migrating existing networks to IMS are also summarized.
The document summarizes the features of a cloud-based VoIP softswitch called HostedSwitch. It handles high call volumes with scalability and reliability. It allows for SIP and H.323 integration, codec conversion, and an API for integration. It also offers least cost routing, quality routing, time-based routing, ANI routing, and rerouting. The billing system provides real-time CDRs, flexible billing, profit analysis, and prepaid or postpaid customer billing. Analytics include real-time graphs, dashboards, reports, alerts, and activity logs. HostedSwitch has low upfront costs and allows rapid market entry with a complete VoIP solution and free software updates.
MVTS Pro is a high performance class 4 softswitch with SBC functionality - a carrier-grade solution for efficient VoIP traffic management and wholesale peering.
The document discusses various scenarios and uncertainties around next generation network architectures, including an increasingly fragmented network landscape with multiple providers involved in service delivery. It also summarizes challenges around ensuring quality of service and network resilience as networks transition to IP-based architectures and applications. Customer ownership and retaining control of the customer relationship is a key issue discussed.
Brian Wood, VP of Marketing at CCPU, summarized the company's 2009 milestones and dominant trends. The 2009 milestones included adaptive traffic shaping, internet offload, femtocell gateway solutions, and pre-integrated platforms like FlexTCA 3.0 and HSPA+ femto AP kits. The dominant trends highlighted efforts to reduce hardware costs through standards, outsourcing, and commoditization while growing software revenue via portability, scalability, and leveraging open platforms.
PathTrak™ Video Monitoring System for Cable TVAndrew Tram
The document describes PathTrak, a video monitoring system that monitors video quality all the way to the RF edge. It discusses how most providers only monitor the backbone or content origination points, missing issues at the edge. PathTrak uses probes like the VSA and RSAM5800 to monitor MPEG streams and RF signals at the edge. This helps identify issues quickly without relying on customer complaints, reducing trouble tickets and churn.
MVTS II is a 4-in-1 wholesale VoIP business platform with integrated switching, billing, routing (LCR, quality-based routing), and border control functionality. It is designed to increase the efficiency of VoIP traffic management in large-scale networks and features SIP-H.323 protocol interworking, distributed architecture, high CC and CPS capacity, and more.
The FRAFOS ABC Session Border Controller combines secure border control, signaling mediation, call routing, and advanced media server applications. It provides a customizable and scalable solution for securing peering connections and subscriber access for VoIP and NGN operators. As an open platform, the ABC SBC can be adapted according to customer needs and deployed on various hardware sizes to accommodate performance requirements of operators of all sizes.
This document introduces the MVTS II, a complete VoIP solution from ALOE Systems comprising softswitch features, routing, billing, and border control. The MVTS II provides real-time profitability controls, jurisdictional routing, flexible routing options, call admission control, protocol interworking, billing, traffic statistics, and alerts. It can handle up to 150,000 concurrent calls and 3,500 new calls per second, supports various protocols and codecs, and has a distributed architecture for scalability and redundancy.
CDMA Wireless Intelligent Network for Advanced Short Messaging ServicesShameer KC
This document proposes implementing an intelligent CDMA network framework called WIN-SMS that would allow for advanced SMS services. It details trigger detection points and messaging that would need to be defined to support WIN processing for SMS scenarios. This would provide a common billing platform and ability to implement advanced SMS features similarly to voice call services. Some key benefits include easier development of new services and a unified approach to billing, though it could impact network capacity. The framework would distribute service logic across network components using standardized interfaces.
The document discusses the CarrierNet solution which brings carriers and networks together to offer migration to an all-IP architecture and high-margin service delivery opportunities. It provides a complete solution for profitable VoIP deployments, interconnects, and value-added services. CarrierNet offers a software-centric platform with softswitch capabilities and media gateways to provide scalable deployment options for applications including VoIP transport, peering, and termination.
The document discusses MPLS VPN and Reliance Communications' MPLS VPN solution. It provides an overview of MPLS VPN and its benefits, including flexibility, scalability, security, and quality of service. It then describes Reliance's MPLS network and data centers, and how their solution addresses challenges around performance, security and flexibility for corporate networks.
The document describes a WebRTC gateway product that connects browser-based telephony using WebRTC standards to traditional VoIP networks and devices using SIP. The gateway allows users on any WebRTC-supported browser to make audio and video calls to SIP phones and networks, integrating browser communication into web applications without APIs or SDKs. It also provides security features like TLS encryption for calls between browsers and the gateway. The gateway can be quickly deployed on cloud platforms like Amazon Web Services.
This document discusses traffic management in networking and telecommunications equipment. It begins with background information on traffic management and its purposes. It then discusses several applications of traffic management including in access networks, metropolitan networks, and mobile networks. For each application, it describes the specific considerations and functions of traffic management systems at different levels in the network.
Basics of performance measurement in umtsEkwere Udoh
This document discusses performance measurement in UMTS networks. It provides definitions for key performance indicators (KPIs) and explains how KPIs can be calculated from raw performance data collected from network elements. Specifically, it notes that proper KPI definitions require considering factors like protocol message types, network topology, and how measurements are aggregated. The document also outlines the basic approach for performance measurement equipment to capture and filter relevant data from UTRAN interfaces in order to compute meaningful KPIs.
3G & Beyond: What Lies Ahead for Performance Management?TTI Telecom
This document summarizes a presentation on performance management challenges for 3G and 4G mobile networks. It discusses the need to correlate performance issues across radio and IP domains to better understand customer experience issues. It also highlights the importance of defining and monitoring key performance indicators (KPIs) specified for LTE networks to track metrics like accessibility, mobility, throughput and latency. The presentation provides examples of using tracking area optimization and multi-service monitoring to improve quality of experience for customers.
IP Multimedia Subsystems Overview - My Training on IMSInam Khosa
This document provides a summary of an presentation on IP Multimedia Subsystem (IMS). It discusses:
- The evolution of 2G, 2.5G, and 3G mobile networks and the birth of IMS as a new architecture.
- IMS allows support for IP-based interactive multimedia services with QoS guarantees across both circuit-switched and packet-switched networks.
- IMS standardization is led by 3GPP and uses SIP, Diameter, and COPS protocols. The presentation covers IMS components, architecture, services control model, and functions.
Kavita Tanwar has over 10 years of experience in IT testing, currently serving as a Testing Technical Lead at Aricent Group. She has extensive experience testing telecom networks, protocols like MAP, SS7, and SIP, and tools like Selenium, HP Quality Centre, and various simulators. The document provides details of her technical skills, projects, and academic qualifications.
SIGTRAN Signaling Gateway, SIGTRAN Signaling Gateway vendor, Capacity between 4 and 128 links, STP/ITP functionality, routing between all combinations of E1 and SIGTRAN accounts. Web interface for setting up accounts and basic routing. Performance: Up to 900 MSU per second, up to 32 E1 links with up to 31 signaling time slots.
The document discusses performance challenges for 3G and beyond networks and key performance indicators. It highlights the need to correlate performance between radio and IP domains to better understand customer experience issues. Tracking area optimization is also discussed as an important metric to balance signaling load and customer traffic for a good user experience. Integrated monitoring of network elements is needed to rapidly identify problems across domains.
The document discusses Intelligent Networks (IN). It provides an overview of IN architecture, standards, services, and key concepts like the IN Conceptual Model and Signaling System No. 7 (SS7). The IN Conceptual Model divides the IN architecture into four planes - service plane, global functional plane, distributed functional plane, and physical plane.
The document provides an overview of the basic components of an Intelligent Network (IN) system. The key components are the Service Control Point (SCP) which handles call setup and processing, the Service Management Point (SMP) which manages subscriber and service data, the Service and User Management (SUM) system which customizes IN services and configurations, the Web Customer Service Control (Web CSC) which provides a web interface for service customization, and the IN Commander which monitors the network elements and allows for database customization.
The document outlines the seven layers of the OSI model from the application layer down to the physical layer. It provides brief descriptions of common protocols and standards used at each layer of the model. The document also includes a diagram mapping many protocols to the appropriate OSI layer and related standards.
This document discusses packet switching, layered models, and protocol suites used in computer networks. It describes the differences between circuit switching and packet switching. It explains how networking tasks are divided into layers, with each layer providing distinct functions. The document outlines the layers of the Internet protocol stack and OSI model, describing the responsibilities of each layer. It provides examples of common protocol suites like TCP/IP that ensure communication systems are complete and efficient.
Brian Wood, VP of Marketing at CCPU, summarized the company's 2009 milestones and dominant trends. The 2009 milestones included adaptive traffic shaping, internet offload, femtocell gateway solutions, and pre-integrated platforms like FlexTCA 3.0 and HSPA+ femto AP kits. The dominant trends highlighted efforts to reduce hardware costs through standards, outsourcing, and commoditization while growing software revenue via portability, scalability, and leveraging open platforms.
PathTrak™ Video Monitoring System for Cable TVAndrew Tram
The document describes PathTrak, a video monitoring system that monitors video quality all the way to the RF edge. It discusses how most providers only monitor the backbone or content origination points, missing issues at the edge. PathTrak uses probes like the VSA and RSAM5800 to monitor MPEG streams and RF signals at the edge. This helps identify issues quickly without relying on customer complaints, reducing trouble tickets and churn.
MVTS II is a 4-in-1 wholesale VoIP business platform with integrated switching, billing, routing (LCR, quality-based routing), and border control functionality. It is designed to increase the efficiency of VoIP traffic management in large-scale networks and features SIP-H.323 protocol interworking, distributed architecture, high CC and CPS capacity, and more.
The FRAFOS ABC Session Border Controller combines secure border control, signaling mediation, call routing, and advanced media server applications. It provides a customizable and scalable solution for securing peering connections and subscriber access for VoIP and NGN operators. As an open platform, the ABC SBC can be adapted according to customer needs and deployed on various hardware sizes to accommodate performance requirements of operators of all sizes.
This document introduces the MVTS II, a complete VoIP solution from ALOE Systems comprising softswitch features, routing, billing, and border control. The MVTS II provides real-time profitability controls, jurisdictional routing, flexible routing options, call admission control, protocol interworking, billing, traffic statistics, and alerts. It can handle up to 150,000 concurrent calls and 3,500 new calls per second, supports various protocols and codecs, and has a distributed architecture for scalability and redundancy.
CDMA Wireless Intelligent Network for Advanced Short Messaging ServicesShameer KC
This document proposes implementing an intelligent CDMA network framework called WIN-SMS that would allow for advanced SMS services. It details trigger detection points and messaging that would need to be defined to support WIN processing for SMS scenarios. This would provide a common billing platform and ability to implement advanced SMS features similarly to voice call services. Some key benefits include easier development of new services and a unified approach to billing, though it could impact network capacity. The framework would distribute service logic across network components using standardized interfaces.
The document discusses the CarrierNet solution which brings carriers and networks together to offer migration to an all-IP architecture and high-margin service delivery opportunities. It provides a complete solution for profitable VoIP deployments, interconnects, and value-added services. CarrierNet offers a software-centric platform with softswitch capabilities and media gateways to provide scalable deployment options for applications including VoIP transport, peering, and termination.
The document discusses MPLS VPN and Reliance Communications' MPLS VPN solution. It provides an overview of MPLS VPN and its benefits, including flexibility, scalability, security, and quality of service. It then describes Reliance's MPLS network and data centers, and how their solution addresses challenges around performance, security and flexibility for corporate networks.
The document describes a WebRTC gateway product that connects browser-based telephony using WebRTC standards to traditional VoIP networks and devices using SIP. The gateway allows users on any WebRTC-supported browser to make audio and video calls to SIP phones and networks, integrating browser communication into web applications without APIs or SDKs. It also provides security features like TLS encryption for calls between browsers and the gateway. The gateway can be quickly deployed on cloud platforms like Amazon Web Services.
This document discusses traffic management in networking and telecommunications equipment. It begins with background information on traffic management and its purposes. It then discusses several applications of traffic management including in access networks, metropolitan networks, and mobile networks. For each application, it describes the specific considerations and functions of traffic management systems at different levels in the network.
Basics of performance measurement in umtsEkwere Udoh
This document discusses performance measurement in UMTS networks. It provides definitions for key performance indicators (KPIs) and explains how KPIs can be calculated from raw performance data collected from network elements. Specifically, it notes that proper KPI definitions require considering factors like protocol message types, network topology, and how measurements are aggregated. The document also outlines the basic approach for performance measurement equipment to capture and filter relevant data from UTRAN interfaces in order to compute meaningful KPIs.
3G & Beyond: What Lies Ahead for Performance Management?TTI Telecom
This document summarizes a presentation on performance management challenges for 3G and 4G mobile networks. It discusses the need to correlate performance issues across radio and IP domains to better understand customer experience issues. It also highlights the importance of defining and monitoring key performance indicators (KPIs) specified for LTE networks to track metrics like accessibility, mobility, throughput and latency. The presentation provides examples of using tracking area optimization and multi-service monitoring to improve quality of experience for customers.
IP Multimedia Subsystems Overview - My Training on IMSInam Khosa
This document provides a summary of an presentation on IP Multimedia Subsystem (IMS). It discusses:
- The evolution of 2G, 2.5G, and 3G mobile networks and the birth of IMS as a new architecture.
- IMS allows support for IP-based interactive multimedia services with QoS guarantees across both circuit-switched and packet-switched networks.
- IMS standardization is led by 3GPP and uses SIP, Diameter, and COPS protocols. The presentation covers IMS components, architecture, services control model, and functions.
Kavita Tanwar has over 10 years of experience in IT testing, currently serving as a Testing Technical Lead at Aricent Group. She has extensive experience testing telecom networks, protocols like MAP, SS7, and SIP, and tools like Selenium, HP Quality Centre, and various simulators. The document provides details of her technical skills, projects, and academic qualifications.
SIGTRAN Signaling Gateway, SIGTRAN Signaling Gateway vendor, Capacity between 4 and 128 links, STP/ITP functionality, routing between all combinations of E1 and SIGTRAN accounts. Web interface for setting up accounts and basic routing. Performance: Up to 900 MSU per second, up to 32 E1 links with up to 31 signaling time slots.
The document discusses performance challenges for 3G and beyond networks and key performance indicators. It highlights the need to correlate performance between radio and IP domains to better understand customer experience issues. Tracking area optimization is also discussed as an important metric to balance signaling load and customer traffic for a good user experience. Integrated monitoring of network elements is needed to rapidly identify problems across domains.
The document discusses Intelligent Networks (IN). It provides an overview of IN architecture, standards, services, and key concepts like the IN Conceptual Model and Signaling System No. 7 (SS7). The IN Conceptual Model divides the IN architecture into four planes - service plane, global functional plane, distributed functional plane, and physical plane.
The document provides an overview of the basic components of an Intelligent Network (IN) system. The key components are the Service Control Point (SCP) which handles call setup and processing, the Service Management Point (SMP) which manages subscriber and service data, the Service and User Management (SUM) system which customizes IN services and configurations, the Web Customer Service Control (Web CSC) which provides a web interface for service customization, and the IN Commander which monitors the network elements and allows for database customization.
The document outlines the seven layers of the OSI model from the application layer down to the physical layer. It provides brief descriptions of common protocols and standards used at each layer of the model. The document also includes a diagram mapping many protocols to the appropriate OSI layer and related standards.
This document discusses packet switching, layered models, and protocol suites used in computer networks. It describes the differences between circuit switching and packet switching. It explains how networking tasks are divided into layers, with each layer providing distinct functions. The document outlines the layers of the Internet protocol stack and OSI model, describing the responsibilities of each layer. It provides examples of common protocol suites like TCP/IP that ensure communication systems are complete and efficient.
This document discusses reference models for computer networks, including the OSI model and TCP/IP model. It provides details on each of the seven layers of the OSI model, including the layer name and number, example protocols, and key functions. It notes that the OSI model was developed by the International Organization for Standardization while TCP/IP was initially designed by the U.S. Department of Defense. It concludes that it will use the hybrid reference model as the framework.
The document provides an overview of IP addressing and networking concepts. It begins with an agenda that includes layers, TCP/IP layers, what IP is, IPv4 structure, binary basics, IP classes, subnetting and tools. It then discusses layers models like OSI and TCP/IP, describing each layer. It defines what an IP is, the structure of an IPv4 address in binary, and common networking terms like ports, protocols, and IP classes. The document provides a high-level introduction to fundamental IP networking concepts.
LTE and DPI technologies are essential for managing mobile broadband networks due to increasing bandwidth demands outpacing supply growth. DPI allows for prioritization of real-time traffic like voice and video, security measures, and new revenue opportunities through traffic analysis and service differentiation. It provides a "smart pipe" for optimized network efficiency and subscriber services. Rapid adoption of smartphones, internet video, and mobile applications is driving network traffic growth that LTE and DPI solutions can help address.
This document discusses IP addressing, subnet masks, default gateways, and the organizations that manage IP addresses. It describes public and private IP addresses and the different IP address classes. It also provides an overview of the 7-layer OSI model and describes each layer's function. Finally, it mentions some common protocol port numbers and introduces Cisco routers and switches.
computer network and chapter 7 OSI layers.pptxgadisaAdamu
The document discusses several key network models and protocols. It provides an overview of the OSI 7-layer model and describes the functions of each layer. It also covers the TCP/IP 5-layer model and compares it to the OSI model. Several important application layer protocols are defined, including HTTP, HTTPS, SMTP, FTP, SNMP, DNS, and Telnet. The document aims to explain the fundamentals of network communication standards and protocols.
The document discusses Point-to-Point Protocol (PPP) and its roles in both wired and wireless internet access. PPP is used to establish and configure connections between two nodes and encapsulate network layer protocol packets for transmission over serial links. It consists of a Link Control Protocol (LCP) for link configuration and establishment and Network Control Protocols (NCPs) like IPCP for network layer configuration. The document examines how PPP is used for dial-up connections, WAP over CSD and GPRS, and using mobile phones as modems through PPP dial-in. Protocol analysis of an MMS transmission over HTTP, TCP, IP and PPP over CSD is also presented.
This document discusses software defined networks (SDN). SDN separates the network control plane from the data plane, allowing a control plane to control multiple devices. The SDN architecture has three layers - the infrastructure layer consists of switches and routers that collect network status and process packets, the control layer bridges the application and infrastructure layers using a high-level language and network status information, and the application layer offers services through the control layer like load balancing and security. OpenFlow is a protocol that exchanges messages between controllers and switches to implement SDN functionality. SDN provides benefits like improved performance, flexibility, and reduced costs compared to traditional networks.
Everything you need to know about network troubleshooting can be learned in elementary school. Networking involves hardware and software that allows computers to communicate. No two networks are exactly alike. Basic network components include end stations, applications, and the network itself. The OSI model provides a standard way to understand how data moves through a network via different layers. TCP/IP is the most common network protocol and uses IP for addressing and routing and TCP for reliable data delivery. Gathering basic network statistics is an important part of troubleshooting.
This document discusses managing multi-layer networks and the challenges of closing the control loop in autonomic networks. It proposes using the Recursive InterNetwork Architecture (RINA) model, which provides a common structure and set of protocols across layers to simplify network management. RINA could reduce costs and downtime compared to the Internet Protocol (IP) model with its many isolated protocols for each layer. The document provides examples of how data center networks and service provider networks could be modeled and managed using RINA.
The seven layers of the OSI reference model are:
1. Physical layer - deals with physical connections and transmission of raw bits of data.
2. Data link layer - deals with node-to-node delivery and error checking between two directly connected machines.
3. Network layer - deals with packet routing across multiple nodes and logical addressing.
Network protocols are sets of rules that govern communications between computers on a network. They configure characteristics like cabling, topology, and bandwidth. The OSI model is an industry standard that defines seven layers of functions for communication between any two points on a network. Each layer has a specific role, with the lowest layers involving physical networking and higher layers dealing with applications and data. Protocols at each layer work together to establish consistent rules for exchanging data and messages between networked devices.
This document provides an overview of LTE technology from Huawei, including:
1. It describes the evolution of radio technologies leading up to LTE, which can achieve downlink speeds of 100Mbps and uplink speeds of 50Mbps.
2. It explains the LTE network architecture, which uses a flat, simplified design compared to previous standards. Key elements include the E-UTRAN, EPC, and interfaces like S1 and X2.
3. It introduces LTE air interface principles like OFDMA for downlink multiple access and SC-FDMA for uplink multiple access, allowing high spectrum efficiency through orthogonal frequency division.
IP resides at the network layer and provides logical addressing that allows systems on different logical networks to communicate. It is a connectionless protocol that does not provide reliability, flow control, or sequencing. VoIP uses RTP, which sits atop UDP, to transport real-time voice data in an efficient manner without retransmissions. UDP is used instead of TCP for VoIP as reliability is less important than latency for real-time voice communications.
The network layer is responsible for routing data across interconnected networks through logical addressing and packet encapsulation. It uses protocols like IP, ICMP, and routing protocols to determine the best path and encapsulate higher layer data into packets with a network header for transmission. Functions include routing, fragmentation and reassembly, and providing a logical addressing scheme independent of physical hardware addresses.
IP resides at the network layer of the OSI model and provides logical addressing that allows systems on different logical networks to communicate. IP packets contain source and destination addresses as well as other fields. Transport protocols like UDP and TCP run on top of IP, with UDP being connectionless and used for real-time voice traffic in VoIP due to its simplicity and lower latency compared to TCP, which provides reliability but higher latency through mechanisms like acknowledgments and retransmissions. RTP runs on top of UDP to provide additional timestamping and sequencing information important for applications like voice calling.
Service Delivery Networking for Next-Gen InfrastructuresF5 Networks
F5 announces new service delivery solutions to help service providers cost-effectively support the growth of mobile traffic, including 9 new solutions and 2 new NEBS compliant hardware platforms available by the end of 2010. These solutions address the increasing operational complexity and costs of traditional approaches and establish a new category of service delivery networking. F5's service delivery network utilizes integrated products to provide strategic points of control through traffic steering, policy enforcement, load balancing, optimization, and edge services to help service providers manage and control increasing data loads.
Service Delivery Networking for Next-Gen Infrastructures
protocolposter
1. W O R L D O F P R O T O C O L S 1 9 9 9 - 2 0 0 0
From
X.25
From
Token Ring
To
SNMP
From
FDDI
SAP
Service
Advertising
Protocol
BMP
Burst
Mode Type
Novell NetWare
To
SMB
Error (IPX)
ISO
Routing
Routing
Responsible for meaningful exchange
of data. Performing generally useful
transformations on data to provide a
standardized application interface and common
communications services, it also provides
services such as encryption, text compression
and reformatting.
6
Presentation Layer
Tunneling
ATMP
Ascend
Tunnel
Management
Protocol
L2TP
Layer 2
Tunneling
Protocol
L2F
Layer 2
Forwarding
Protocol
PPTP
Point to Point
Tunneling
Protocol
To
PPP
To
X.25
To
Ethernet
From
CLNP
MNLP
Mobile Network
Location
Protocol
IPX PING
Echo (IPX)
From
Ethernet
NDS
NetWare
Directory
Service
NCP
NetWare
Core
Protocol
NetWare Lite
NLP
NetWare
Lite
Protocol
LSP
NetWare
Lite
Sideband
Protocol
Routing
IPX WAN
NLSP
Netware
Link
Services
Protocol
RIP
(NOVELL)
Routing
Information
Protocol
U-B
Ungermann
-Bass
Header
XNS
Courier
To
SMB
Error (XNS)
Echo (XNS)
RIP (XNS)
Routing
Information
Protocol
IDP
Internet
Datagram
Protocol
NetBIOS
(3COM)
XNS
Virtual
Terminal
XNS
Filing
XNS
Mail
XNS
Printing
To
SMB
Interface Standards
HSSI
High Speed Serial
Interface
V.11
or
X.21
RS-530V.36
or
RS-449
V.35V.24
or
RS-232
To
XNS
To
IP
To
SNA
To
IPX
To
IDP
To
TCP
To
DDP
To
ISO
Control Protocols
IPCP
Internet Protocol
Control
Protocol
OSINLCP
OSI Network
Layer Control
Protocol
ATCP
AppleTalk
Control
Protocol
XNSCP
XNS
Control
Protocol
NBFCP
NetBios Frames
Control Protocol
LEXCP
LAN Extension
Control
Protocol
BACP
Bandwidth
Allocation Control
Protocol
CSCP
Cisco Systems
Control
Protocol
SNACP
SNA
Control
Protocol
SDCP
PPP Serial
Data Control
Protocol
CLLM
Consolidated
Link Layer
Management
Q.933
Annex A
T1.617
Annex D
SVC (Frame Relay)
Switched Virtual
Connection
Control Message
LMI
(Frame Relay)
Local
Management
Interface
To
ATM Cell
www.protocols.comProtocol information and updates: RADCOM home page: www.radcom-inc.com
To
Ethernet
To
Token Ring
To
FDDI
ECP
Encryption
Control
Protocol
IPXCP
Internetwork
Packet Exchange
Control Protocol
IP Security
ESP
IP
Encapsulation
Security
Payload
AH
IP
Authentication
Header
Data
Responsible for addressing and control
functions (e.g., routing) necessary to
move data through the network. This
covers establishing, maintaining and terminating
connections including packet switching, routing,
data congestion, reassembly of data and
translation of logical addresses to physical
addresses.
Network Layer
3
Responsible for error-free transmission
and establishing logical connections
between stations. This is achieved by
packaging raw bits from the physical layer into
blocks of data (frames) and sending these frames
with the necessary synchronization, error control
and flow control.
Data Link Layer
2
Responsible for the transmission of
unstructured bit streams over a physical
medium. This covers the mechanical,
electrical and procedural characteristics required
to establish, maintain and deactivate physical
links.
Physical Layer
1
DATALINKPHYSICAL
Address Resolution
SDH/SONET
DUP
Data User Part
B-ISUP
B-ISDN
User Part
From
ATM
Telephony (SS7, V5, Cellular)
ISUP
ISDN
User Part
TUP
Telephone User
Part
TCAP
Transaction
Capabilities
Application Part
MTP1
Message Transfer
Part Level 1
X.25
PPP
Presentation
Services
Session Layer
Responsible for support of connections
between sessions, administrative tasks
and security. Providing the control
structure for communication between applications,
it establishes, manages and terminates
connections (sessions) between cooperating
applications.
5
Responsible for interaction with the
operating system and providing
interface to the system (e.g., FTP, TELNET,
SMTP). Serving as a window for applications to
access network services, it handles general
network access, flow control, error recovery and
file transfers.
7
Application Layer
Responsible for reliable, transparent
transfer of data between end points.
Providing end-to-end error recovery and
flow control, it deals with packet handling,
repackaging of messages, dividing messages into
smaller packets and error handling.
4
Transport Layer
7
6
5
4
3
2
1
Product brand names may be trademarks of their respective owners and are mentioned for reference only. Information subject to change without notice. RADCOM makes no warranty of any kind, expressed or implied, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose. RADCOM is not liable for errors contained herein.
PHYSICAL
MTP2
Message Transfer
Part Level 2
MTP3
Message Transfer
Part Level 3
POS-WOPv.L.0
GSM/CDMA
SNA Transactions Services
DDM
Distributed Data
Management
DCA
Document
Control
Architecture
DIA
Document
Interchange
Architecture
SNA/DS
Distributed
Services
SNA/MS
Management
Services
SNA/FS
File Services
Control
PDH-G.804
DS1
1.544 Mbps
DS2/J2
6.24 Mbps
E1 PLCP
E1
2.048 Mbps
E3 PLCP
E3
34.368 Mbps
DS4
140 Mbps
DS3
45 Mbps
Routing
V5
NETWORKTRANSPORTSESSIONPRESENTATIONAPPLICATION
NETWORKTRANSPORTSESSIONPRESENTATIONAPPLICATION
GPRS
Supplementary Services
Audio Signal
G.711
G.722
G.723.1
G.729
G.728
Video
Signal
H.261
H.263
Frame Relay
Copper
Twisted
Pair CDDI
100 Mbps
Shielded
Twisted
Pair SDDI
100 Mbps
Fiber
Optic
100 Mbps
DATALINK
To
IP
To
X.25
From
Frame
Relay
From
UDP
T.125/T.122
(MCS)
T.124 (GCC)
IP Switching
MPLS
Multi Protocol
LabelSwitching
TDP
TagDistribution
Protocol
From
NetBIOS
From
SPX
SPXII
From
UDP
RPC
Remote
Procedure
Call
To
Frame
Relay
To
Ethernet
To
DS1
To
Token Ring
xDSL
Signaling
UNI
(ATM)
Q.2931
Q.2971
From
E1,E3
From
T1,T3
Q.93B
Q.SAAL
CES
Circuit Emulation
Service
ILMI (ATM)
Interim Local
Management
Interface
OAM (ATM)
Operations
and
Maintenance
SSCOP
Service-Specific
Connection-
Oriented
Protocol
PNNI (ATM)
Private
Network-
to-Network
Interface
Q.2140 (SS7)
CIF
Cell In Frames
MPOA
Multi Protocol
Over ATM
ATM Cells
DXI (ATM)
Data Exchange
Interface
HDSL
High Bit Rate
DSL
SDSL
Symmetric
DSL
RADSL
Rate Adaptive
DSL
ADSL
Asymmetric
DSL
TAXI
100 Mbps
25 Mbps
ATM
10 BASE-T
100 BASE-T
10 BASE-5
10 BASE-2
10 BASE-F 100 BASE-F
10 BROAD 36
1 BASE -5
To
Frame
Relay
From
SNAP
From
SMDS
XTP
Express
Transport
Protocol
IEEE 802.1p
ISO 9577
ETHERTYPE
V,E,T Series
LLC 802.2
MAC
(Token Ring)
Medium
Access
Control
RI
Source
Routing
Indicators
IEEE
802.5
Token
Ring
FDDI
Fiber
Distributed
Data Interface
100
VG-AnyLAN
SLIP
Serial Line
Interface
Protocol
LMI (SMDS)
Local Management
Interface
SMDS
DXI (SMDS)
Data Exchange
Interface
IEEE 802.1Q
STUN-SDLC
Serial
Tunneling
of SDLC
ICMP
Internet
Control
Message
Protocol
BOOTP
Bootstrap
Protocol
DHCP
Dynamic
Host
Configuration
ProtocolPIM
Protocol
Independent
Multicast
IGMP
Internet
Group
Management
Protocol
ARP
Address
Resolution
Protocol
RARP
Reverse
Address
Resolution
Protocol
IARP
Inverse
Address
Resolution
Protocol
SLARP
Cisco
Serial Line
Address
Resolution
Protocol
Trailers
Berkeley
Trailers
Encapsulation Wellfleet
SRB
Wellfleet
SourceRoute
Bridging
RSVP
Resource
Reservation
Protocol
RSRB
Cisco
Remote Source
Route Bridging
H.323
DSMCC
(MPEG)
Digital Storage
Media Protocol
RTSP
Real-Time
Streaming
Protocol
TCP/IP
GDP
Cisco
Gateway
Discovery
Protocol
Mobile IP
Mobile Internet
Protocol
UDP
User
Datagram
Protocol
NetBIOS-
DGM
(TCP/IP)
Datagram
Protocol
SIP L3
SMDS
Interface
ProtocolLevel3
DXI (Cisco)
Data Exchange
Interface
SIP L2
SMDS
Interface
ProtocolLevel2
IP
Internet
Protocol
CSLIP
Compressed
Slip
SMT
FDDI
Station
Management
MAC
(FDDI)
Medium
Access
Control
T.126 (SI)
T.127 (MBFT)
To
TCP
To
IP
LAN
X.224.0
(ISO TP)
From
TCP
From
X.25
From
IPX
From
Q.922
ATM
Security
ISAKMP
Internet
Security
Association
and Key
Management
Protocol
SSH
Secure Shell
HTTPS
Secure HTTP
RADIUS
Remote
Authentication
Dial In User
Service
TCP
Transport
Control
Protocol
From
TCP
SNAP
Sub-Network Access Protocol
STM-16
0C-48
2488
Gbps
STM-1
0C-3
155.520
Mbps
OC-1
51.840
Mbps
STM-4
0C-12
622
Mbps
V5
LAPV5
XNSSUN NFS IBM
NetBIOS
NetBEUI
RPL
Remote
Program
Load
From
SDLC
DLSw
Data Link
Switching:
Switch-to-Switch
Protocol
SSP
HPR
High
Performance
Routing
APPN
Advanced Peer
to Peer
Networking
Path Control
SMB
Server
Message
Block
Data Flow Control
LU 6.2
Logical Unit 6.2
Transmission Control
Request/ Response Header
To
SNA
SDLC
Synchronous
Data Link
Control
SCS
SNA Character
Stream
IPDS
Intelligent
Printer Data
Stream
3270
Data Stream
IBM RT
Distributed
Services
Header
LAP
(AppleTalk)
Link Access
Protocol
From
UDP
AARP
AppleTalk
Address
Resolution
Protocol
Tunneling
(AppleTalk)
RTMP
Routing
Table
Maintenance
Protocol
AURP
AppleTalk
Update
Routing
Protocol
AEP
AppleTalk
Echo
Protocol
ZIP
Zone
Information
Protocol
Postscript
ASP
AppleTalk
Session
Protocol
PAP
Printer
Access
Protocol
TOPS
SoftTalk
ADSP
AppleTalk
Data
Stream
Protocol
NBP
(AppleTalk)
Name
Binding
Protocol
ATP
AppleTalk
Transaction
Protocol
KSP
Kiewit
Stream
Protocol
AppleTalk
AFP
AppleTalk
Filing
Protocol
To
IP
RRM
Radio
Resource
Management
CDPD
MAC (CDPD)
Medium Access
Control
(Cellular Digital
Packet Data)
Cellular
Modems
AirLink SecurityMNRP
Mobile Network
Registration
Protocol
MDLP
Mobile Data
Link Protocol
SNDCP
Subnetwork-
Dependent
Convergence
Protocol
DDP
Datagram
Delivery
Protocol
ISDN
To
TCP
LAPB
Link Access
Procedure
Balanced
VLR
VisitorLocation
Register
AUC
Authentication
Center
HLR
HomeLocation
Register
EIR
Equipment
Identity
Register
INAP
Intelligent Network
Application Protocol
IS41/MAP
Mobile
Application Part
IPX
Internet
Packet
Exchange
ES-IS
End System to
Intermediate
System
Routing
IS-IS
Intermediate
Routing
Protocol
IDRP
Interdomain
Routing
Protocol
IBM NM
IBM
Network
Management
Remote Unix
SIP L1
SMDS
Interface
ProtocolLevel1
International Headquarters: Radcom Ltd., 12 Hanechoshet Street, Tel-Aviv 69710, Israel Tel: +972-3-6455055, Fax: +972-3-6474681, E-mail: info@radcom.co.il
TFTP
Trivial File
Transfer
Protocol
NTP
Network
Time
Protocol
POP3
Post
Office
Protocol
Version3
From
TCP
RIP
(TCP/IP)
Routing
Information
Protocol
BGP
Border
Gateway
Protocol
E-IGRP
Cisco
Enhanced
IGRP
OSPF
Open
Shortest
Path
First Protocol
NHRP
Next
Hope
Routing
Protocol
IGRP
Cisco
Inter-Gateway
Routing
Protocol
EGP
Exterior
Gateway
Protocol
GRE
Generic Routing
Encapsulation
GGP
Gateway to
Gateway
Protocol
HSRP
Hot Standby
RouterProtocol
NARP
NBMA
Address
Resolution
Protocol
From
X.25
From
SLIP CSLIP
From
PPP
To
ISOTP
To
ND
To
XTP
IEEE
802.4
Token Bus
IEEE
802.3
CSMA/CD
IEEE 802.6
DQDB
Distributed
Queue
Dual Bus
BPDU
Bridge
Spanning
Tree
Protocol
Carrier
Phase
Coherent
Broadband
Multilevel
Duobinary
Carrier
Phase
Continuous
From
SNA
From
TCP
From
UDP
QLLC
Qualified
Logical
Link
Control
From
X.25
From
TCP
HDLC
High-Level
Data-Link
Control
From
IP
From
SPP
NWWDOG
NetWare
Watchdog
Protocol
NWBCAST
NetWare
Broadcast
Message
Notification
NWDIAG
IPX
Diagnostic
Support
Protocol
NWSERIAL
Novell
Serialization
Protocol
PAD
(X.29)
Packet
Assembly/
Disassembly
MLP
(X.25)
Multi-Link
Protocol
From
LAPB
From
LAPB
To
PPP
To
QLLC
To
IP
X.25
Packet
Layer
Protocol
X.75
Packet Switched
Signaling
between
Public Networks
SPX
Sequenced
Packet
Exchange
SPX II
Sequenced
Packet
Exchange
NetBIOS
(Novell)
ASP (CDPD)
Accounting
Services
Protocol
Wellfleet PPP
Router/Bridge
To
SMB
To
MDLP
ISO PP
Presentation
Protocol
ISO SP
Session
Protocol
NetBIOS
(ISO)
CLNP
Connectionless
Network
Protocol
From
ISO DE
CMIP
Common
Management
Information
Protocol
FTAM
File
Transfer,
Access and
Management
VTP
Virtual
Terminal
Protocol
X.500
Directory
Services
MMS
Manufacturing
Messaging
Service
ODA
Office
Document
Architecture
X.400
Electronic
Mail
CMISE
Common
Management
Information
Service Element
ISO TP
Transport
Protocol
ROSE
Remote
Operations
Service
Element
ACSE
Association
Control
Service
Element
RTSE
Reliable
Transfer
Service
Element
H.235
H.245 H.225
(Q.931)
H.450.2H.450.3
From
TPKT
BSSMAP
Base Station
System
Management
Application Part
DTAP
Direct Transfer
Application Part
SCCP
Signaling
Connection
Control Part
BSSAP
Base Station
System
Application Part
BTSM
BSC-BTM
Interface
Layer 3
From
LAPD
RAS
Registration
Admissions
and Status
RTCP
Real-Time
Transport
Control
Protocol
RTP
Real-Time
Transport
Protocol
NIS
Network
Information
Services
RSTAT
Remote
Statistics
NFS
Network
File
System
PMAP
Port
Mapper
MOUNT
Mount
Server
From
IP
ND
SUN
Network
Disk
MPEG-2
Motion Picture
Expert Group
AAL2AAL1 AAL5AAL3/4
To
Frame Relay
LAPD
Link Access
Procedure D
Channel
Q.931
NS-Network
GTP
GPRS
Tunneling
Protocol
GMM
GPRS
Mobility
Management
SMS
Short
Message
Service
NM
Network
Management
SNDCP
Sub Network
Dependent
Convergence
Protocol
US Office: Radcom Equipment Inc., 575 Corporate Drive, Mahwah, NJ 07430, USA. Tel: (201) 529-2020, Fax: (201) 529-0808,1-800-RADCOM-4
IEEE 802.3z
Gigabit Ethernet
1000 BASE-LX
1000 BASE-SX
Unshielded
Twisted
Pair
4/16 Mbps
Fiber
Optic
4/16 Mbps
Shielded
Twisted
Pair
4/16 Mbps
IMAP4
Internet
Message
Access
Protocol
SMTP
Simple
Mail
Transfer
Protocol
TelnetFTP
File
Transter
Protocol
X Windows HTTP
WWW
Hyper Text
Transfer
Protocol
TACACS+
Access
Control
Protocol
TACACS
Access
Control
Protocol
PRINT
Remote
Unix
Print (Ipr)
REXEC
Remote
Unix
Exec
RWHO
Remote
UnixWHO
Protocol
RLOGIN
Remote
Unix
Login
RSHELL
Remote
Unix
Shell
CCP
Compression
Control
Protocol
SPCP
Stream Protocol
Control
Protocol
BAP
Bandwidth
Allocation
Protocol
LQR
Link
Quality
Report
LCP
Link
Control
Protocol
LEX
LAN
Extension
Protocol
CHAP
Challenge
Handshake
Authentication
Protocol
EAP
Extensible
Authentication
Protocol
PAP
Password
Authentication
Protocol
SDTP
PPP Serial
Data Transport
Protocol
LZS
Compression
Protocol for PPP
MPPC
Microsoft PPP
Compression
Protocol
MLP (PPP)
Multi-Link
Protocol
BCP
Bridging
Control
Protocol
V5
PSTN
V5
CONTROL
V5
BCC
V5
PROTECTION
V5
LINK
CONTROL
Internet Management
SNMP
Simple
Network
Management
Protocol
CMOT
CMIP
over TCP
SPP
Sequenced
Packet
Protocol
PEP
Packet
Exchange
Protocol
TPKT
OSI
Upper TCP/IP
ISO DE
ISO
Development
Environment
DVMRP
Distance Vector
Multicast
RoutingProtocol
XOT
Cisco Systems
X.25 over TCP
NetBIOS-
SSN
(TCP/IP)
Session
Protocol
DNS
Domain
Name
Server
NetBIOS-
NS
(TCP/IP)
Name
Server
LDAP
Light
Weight
Access
Protocol
To
MPTN
To
SMB
To
X.25
To
ISO TP
To
ISDN
To
DLSw
H.450.1
To
SMB
To
Token
Ring
From
TCP
To
SDLC
To
RI
RR
Radio
Resource
MM
Mobility
Management
SMS
ShortMessage
Service
CM/CC
Connection
Management
Call Control
SS
Supplementary
Services
To
LAPB
MPTN
AnyNet
Multi-Protocol
Transport
Networking
To FTP
Telnet
DS1 PLCP
OS1
1.544 Mbps
DSO
PLCP
64 kbps
DS3 PLCP
OS3
45 Mbps
G.703 PLCP
ISDN-H12
1.920 Kbps
ISDN-H11
1.563 Kbps
ISDN-HO
384 Kbps
ISDN-B
64 Kbps
ISDN-D
16 Kbps BRI
64 Kbps PRI
Cisco SLE
Cisco Serial
Line
Encoding
Frame Relay
Link Access
Procedure to Frame
Mode Bearer
Services (LAPF)
PPP-BPDU
PPP Bridging
Protocol
PPP
Point-to-Point
Protocol
LANE (ATM)
LAN Emulation
Ethernet
DIX
V2
BSSGP
Base Station
System
GPRS
Protocol
Ethernet
50 ohm
coax
Thin Wire
50 ohm
coax
Broadband
75 ohm
coax
Modem Standards
V.26 bis
2400 bps
V.26
2400 bps
V.22 bis
2400 bps
AT&T 209
9600 bps
V.22
AT&T 212
1200 bps
V.21
AT&T 103
300 bps
V.42 bisV.42V.33
14.4 kbps
V.32
9600 bps
V.29
9600 bps
V.27bis
4800 bps
From
X.400
From
ISO TP