SDN control of disaggregated optical transport networks
377 بار بازدید -
5 سال پیش
-
Software-defined networking (SDN) technology is
Software-defined networking (SDN) technology is an approach to network management that enables dynamic, programmatically efficient network configuration in order to improve network performance and monitoring making it more like cloud computing than traditional network management.SDN is meant to address the fact that the static architecture of traditional networks is decentralized and complex while current networks require more flexibility and easy troubleshooting. SDN attempts to centralize network intelligence in one network component by disassociating the forwarding process of network packets (data plane) from the routing process (control plane). The control plane consists of one or more controllers which are considered as the brain of SDN network where the whole intelligence is incorporated. However, the intelligence centralization has its own drawbacks when it comes to security, scalability and elasticity and this is the main issue of SDN.
SDN was commonly associated with the OpenFlow protocol (for remote communication with network plane elements for the purpose of determining the path of network packets across network switches) since the latter's emergence in 2011. However, since 2012. OpenFlow for many companies is no longer an exclusive solution, they added proprietary techniques. These include Cisco Systems' Open Network Environment and Nicira's network virtualization platform.
SD-WAN applies similar technology to a wide area network (WAN).
SDN architectures decouple network control and forwarding functions, enabling network control to become directly programmable and the underlying infrastructure to be abstracted from applications and network services.
The OpenFlow protocol can be used in SDN technologies. The SDN architecture is:
Directly programmable: Network control is directly programmable because it is decoupled from forwarding functions.
Agile: Abstracting control from forwarding lets administrators dynamically adjust network-wide traffic flow to meet changing needs.
Centrally managed: Network intelligence is (logically) centralized in software-based SDN controllers that maintain a global view of the network, which appears to applications and policy engines as a single, logical switch.
Programmatically configured: SDN lets network managers configure, manage, secure, and optimize network resources very quickly via dynamic, automated SDN programs, which they can write themselves because the programs do not depend on proprietary software.
Open standards-based and vendor-neutral: When implemented through open standards, SDN simplifies network design and operation because instructions are provided by SDN controllers instead of multiple, vendor-specific devices and protocols.
SDMN
Software-defined mobile networking (SDMN)is an approach to the design of mobile networks where all protocol-specific features are implemented in software, maximizing the use of generic and commodity hardware and software in both the core network and radio access network. It is proposed as an extension of SDN paradigm to incorporate mobile network specific functionalities. Since 3GPP Rel.14, a Control User Plane Separation was introduced in the Mobile Core Network architectures with the PFCP protocol.
DENOG
Published on Nov 27, 2018
https://media.ccc.de/v/denog10-38-sdn... Software Defined Networking (SDN) is offering greater operational efficiency and automation by turning the transport network into a programmable resource. Several competing data models for disaggregated and partially disaggregated optical networks currently being developed and proposed by research and standardization are presented and their strengths and challenges discussed. A key use case of SDN for optical transport networks (Transport SDN) is multi-vendor network and service management. The requirement for interoperability drives open and standardized interfaces. This talk will introduce the data models currently being discussed as contenders for application programming interfaces (APIs) of disaggregated and partially disaggregated optical networks on device and network level. In case of fully disaggregated networks, each device is directly controlled by an SDN controller; in case of partial disaggregation, an optical line system (OLS) is operated as a complete system, and the transponders at the edge are operated independently from the OLS and can be directly controlled. The strengths and weaknesses of the two disaggregation models and the considered APIs, including OpenConfig, OpenROADM, IETF TEAS, and ONF Transport API, are discussed in the talk. Current results from ongoing interop events, field trials, and research projects are presented to highlight challenges and solutions for the SDN control of (partially) disaggregated optical networks. Achim Autenrieth https://cfp.denog.de/denog10/talk/HGNLHC
Category
Science & Technology
License
Creative Commons Attribution license (reuse allowed)
SDN was commonly associated with the OpenFlow protocol (for remote communication with network plane elements for the purpose of determining the path of network packets across network switches) since the latter's emergence in 2011. However, since 2012. OpenFlow for many companies is no longer an exclusive solution, they added proprietary techniques. These include Cisco Systems' Open Network Environment and Nicira's network virtualization platform.
SD-WAN applies similar technology to a wide area network (WAN).
SDN architectures decouple network control and forwarding functions, enabling network control to become directly programmable and the underlying infrastructure to be abstracted from applications and network services.
The OpenFlow protocol can be used in SDN technologies. The SDN architecture is:
Directly programmable: Network control is directly programmable because it is decoupled from forwarding functions.
Agile: Abstracting control from forwarding lets administrators dynamically adjust network-wide traffic flow to meet changing needs.
Centrally managed: Network intelligence is (logically) centralized in software-based SDN controllers that maintain a global view of the network, which appears to applications and policy engines as a single, logical switch.
Programmatically configured: SDN lets network managers configure, manage, secure, and optimize network resources very quickly via dynamic, automated SDN programs, which they can write themselves because the programs do not depend on proprietary software.
Open standards-based and vendor-neutral: When implemented through open standards, SDN simplifies network design and operation because instructions are provided by SDN controllers instead of multiple, vendor-specific devices and protocols.
SDMN
Software-defined mobile networking (SDMN)is an approach to the design of mobile networks where all protocol-specific features are implemented in software, maximizing the use of generic and commodity hardware and software in both the core network and radio access network. It is proposed as an extension of SDN paradigm to incorporate mobile network specific functionalities. Since 3GPP Rel.14, a Control User Plane Separation was introduced in the Mobile Core Network architectures with the PFCP protocol.
DENOG
Published on Nov 27, 2018
https://media.ccc.de/v/denog10-38-sdn... Software Defined Networking (SDN) is offering greater operational efficiency and automation by turning the transport network into a programmable resource. Several competing data models for disaggregated and partially disaggregated optical networks currently being developed and proposed by research and standardization are presented and their strengths and challenges discussed. A key use case of SDN for optical transport networks (Transport SDN) is multi-vendor network and service management. The requirement for interoperability drives open and standardized interfaces. This talk will introduce the data models currently being discussed as contenders for application programming interfaces (APIs) of disaggregated and partially disaggregated optical networks on device and network level. In case of fully disaggregated networks, each device is directly controlled by an SDN controller; in case of partial disaggregation, an optical line system (OLS) is operated as a complete system, and the transponders at the edge are operated independently from the OLS and can be directly controlled. The strengths and weaknesses of the two disaggregation models and the considered APIs, including OpenConfig, OpenROADM, IETF TEAS, and ONF Transport API, are discussed in the talk. Current results from ongoing interop events, field trials, and research projects are presented to highlight challenges and solutions for the SDN control of (partially) disaggregated optical networks. Achim Autenrieth https://cfp.denog.de/denog10/talk/HGNLHC
Category
Science & Technology
License
Creative Commons Attribution license (reuse allowed)
5 سال پیش
در تاریخ 1398/05/18 منتشر شده
است.
377
بـار بازدید شده