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{{Short description|IP network architecture}}
{{Multiple issues|
{{refimprove|date=August 2010}}
{{peacock|date=August 2011}}
}}


{{Multiple issues|{{refimprove|date=August 2010}}
'''Flat IP''' architecture provides a way to identify devices using symbolic names, unlike the [[hierarchy|hierarchical]] architecture such as that used in "normal" [[IP address]]es. This form of system is of more interest to mobile broadband network operators.
{{peacock|date=August 2011}}}}
'''Flat IP''' is a network addressing scheme in which each device is assigned a unique identifier within a non-hierarchical address space. Unlike [[Hierarchical internetworking model|hierarchical IP]] addressing methods, Flat IP treats all devices as equal nodes, simplifying routing by eliminating the need for structured [[Subnet|subnetting]].


Flat IP is commonly applied in mobile networks, particularly in [[LTE (telecommunication)|LTE]], due to its efficiency in managing device handovers between network cells. The approach allows each device to be directly accessed through its unique identifier, improving routing efficiency and reducing latency in mobile environments.
== Flat IP architecture ==
To meet customer demand for real-time data applications delivered over mobile broadband networks, wireless operators are turning to flat IP network architectures.


While Flat IP may streamline network design for certain applications, it can present scalability challenges in larger networks. The scheme requires a substantial pool of unique identifiers and lacks a [[Hierarchy|structured hierarchy]], potentially reducing efficiency for large-scale networks compared to traditional IP models. Nonetheless, Flat IP is a practical choice in scenarios where simplicity and direct device access are priorities.
;The key benefits of flat IP architectures are:
*lower costs
*reduced system latency
*decoupled radio access and core network evolution


==Flat IP architecture==
;Key players in recognizing these advantages are:
This [[Computer architecture|architecture]] is suitable for small businesses, home networks, and mobile broadband network operators because it simplifies [[Network monitoring|network management]] and provides a direct link for real-time data applications.<ref name=":0">{{Cite web |last=Tripathy |first=Susnigdha |date=2023-02-21 |title=What Is a Flat Network? Definition, Benefits & How It Works |url=https://www.enterprisenetworkingplanet.com/management/the-risks-and-rewards-of-flat-networks/ |access-date=2024-09-26 |website=Enterprise Networking Planet |language=en-US}}</ref>
*Mobile Networks
*3rd Generation Partnership Project (3GPP)
*3GPP2 standards organizations
*[[WiMAX]] Forum.


=== Overview ===
;Key considerations of Flat IP Architectures for Mobile Networks include:
Wireless operators use Flat IP architecture to address the growing need for real-time data applications delivered over mobile broadband networks. This approach moves away from traditional [[Hierarchy|hierarchical]] network designs, favoring a simplified, horizontal structure.
Advanced base stations that integrate radio control, header compression, encryption, call admission control, and policy enforcement with IP/Ethernet interfaces.
Base station routers will provide simpler, lower-latency 3GPP/2 networks. Key emerging players are: [[Alcatel-Lucent]], [[Airvana]], and Ubiquisys.


=== Benefits of Flat IP Architecture ===
For WCDMA networks, the [[Direct Tunnel]] Architecture is emerging as the most viable evolution path. Currently all major vendors support Direct Tunnel, where the SGSN is bypassed on the user plane. An even further advancement is Nokia-Siemens's Internet High Speed Packet Access ([IHSPA]) architecture which removes also the RNC from the data path thereby simplifying the architecture and reducing latencies even further.<ref>[http://www.nokiasiemensnetworks.com/portfolio/products/mobile-broadband/wcdmahspa/i-hspa ]{{dead link|date=October 2012}}</ref>
Flat IP architectures offer several advantages, including:


# Cost Efficiency: Flat IP networks reduce reliance on specialized network hardware, such as ATM switches and [[Multiprotocol Label Switching|MPLS routers]], by utilizing a single level of communication. This approach lowers both hardware and maintenance costs.
The WiMax Access Services Network was the first standardized IP-centric mobile network architecture establishing principles now being adopted across the industry. Eventually HSPA and LTE networks have been chosen by most operators as their preferred network technology.
# Improved Scalability and Flexibility: The absence of hierarchical layers simplifies the integration of new devices and services, benefiting mobile network operators in rapidly changing technological environments.
# Reduced Latency: By minimizing network layers and simplifying packet processing, flat IP architectures support latency-sensitive applications, such as Voice over IP (VoIP) and video streaming.<ref name=":0" />

In mobile networks, centralized anchors act as performance bottlenecks. Flat, distributed architectures avoid this by not having centralized components, thereby reducing latency and allowing for scalability and flexibility.<ref>{{cite book |last1=Bokor |first1=László |last2=Faigl |first2=Zoltán |last3=Imre |first3=Sándor |title=Flat Architectures: Towards Scalable Future Internet Mobility |date=2011 |publisher=Springer, Berlin, Heidelberg |isbn=978-3-642-20898-0 |url=https://doi.org/10.1007/978-3-642-20898-0_3 |access-date=25 November 2024 |ref=flat_arch}}</ref>

=== Drawbacks and Challenges ===
Despite their benefits, Flat IP architectures present several challenges:

# Lack of Redundancy: Flat networks rely on a single switch or point of failure, making them vulnerable to outages if that switch fails.
# Difficult Troubleshooting: The simplicity of flat networks can complicate troubleshooting. With fewer hierarchical layers to isolate issues, identifying the root cause of network problems can be time-consuming.
# Increased Security Risks: Flat networks are more vulnerable to lateral attacks, where malware or intrusions can spread quickly between devices without traditional segmentation.

=== Use Cases of Flat IP Architecture ===
Flat IP architecture is particularly relevant to mobile networks and is supported by several industry standards organizations, including:

# 3rd Generation Partnership Project (3GPP) and 3GPP2: These organizations develop global standards for mobile telecommunication systems and have adopted flat IP principles in their network designs.
# [[WiMAX]] Forum: The WiMAX Forum, responsible for promoting and certifying wireless broadband technologies, was one of the early adopters of IP-centric mobile networks.

=== Key Considerations for Mobile Networks ===
In mobile networks, flat IP architectures integrate the following components:<ref>{{Cite web |date=2024-06-11 |title=What Is A Flat Network? - ITU Online |url=https://www.ituonline.com/tech-definitions/what-is-a-flat-network/ |access-date=2024-09-26 |language=en-US}}</ref>

# Advanced Base Stations: Modern base stations in flat IP networks handle multiple functions, including radio control, header compression, encryption, call admission control, and policy enforcement. These stations often use IP/Ethernet interfaces to simplify network architecture and reduce latency.
# Direct Tunnel Architecture: In this configuration, user data bypasses the Serving GPRS Support Node (SGSN) on the user plane. Direct Tunnel Architecture, supported by major vendors, reduces latency and complexity. Nokia-Siemens' Internet High-Speed Packet Access (IHSPA) takes this further by removing the Radio Network Controller (RNC) from the data path, resulting in even lower latencies.
# WiMAX Access Services Network (ASN): WiMAX was the first standardized IP-centric mobile network architecture. Although HSPA and LTE networks have since become dominant, many principles from WiMAX ASN remain relevant in modern mobile networks.


==See also==
==See also==
{{portal|Internet}}
* [[3GPP Long Term Evolution]]
* [[3GPP Long Term Evolution]]
* [[All IP]]
* [[All IP]]
Line 36: Line 53:


==External links==
==External links==
*[http://www.tcpipguide.com/free/t_NameSpacesandNameArchitecturesFlatandHierarchical.htm TcpIpGuide]
* [http://www.electrosmart.net/network/Flat-IP-Architecture.php ElectroSmart]
*[http://www.electrosmart.net/network/Flat-IP-Architecture.php ElectroSmart] {{Webarchive|url=https://web.archive.org/web/20071230032522/http://www.electrosmart.net/network/Flat-IP-Architecture.php |date=2007-12-30 }}
* [http://www.tcpipguide.com/free/t_NameSpacesandNameArchitecturesFlatandHierarchical.htm TcpIpGuide]
* [http://www.3gpp.org/ftp/Specs/html-info/25999.htm 3GPP TR 25.999]
*[http://www.alcatel-lucent.com/ Alcatel Lucent]
*[https://iphoneimei.net/check-imei iPhone IMEI Checker]
* [http://www.ubiquisys.com/ Ubiquisys]
* [http://www.alcatel-lucent.com/ Alcatel Lucent]
*[http://www.3gpp.org/ftp/Specs/html-info/25999.htm 3GPP TR 25.999]
* [http://www.airvana.com/ Airvana]
*[http://www.ubiquisys.com/ Ubiquisys]
* [http://www.ericsson.com/ Ericsson]
*[http://www.airvana.com/ Airvana]
*[http://www.ericsson.com/ Ericsson]


{{DEFAULTSORT:Flat Ip}}
{{DEFAULTSORT:Flat Ip}}

Latest revision as of 19:12, 26 November 2024

Flat IP is a network addressing scheme in which each device is assigned a unique identifier within a non-hierarchical address space. Unlike hierarchical IP addressing methods, Flat IP treats all devices as equal nodes, simplifying routing by eliminating the need for structured subnetting.

Flat IP is commonly applied in mobile networks, particularly in LTE, due to its efficiency in managing device handovers between network cells. The approach allows each device to be directly accessed through its unique identifier, improving routing efficiency and reducing latency in mobile environments.

While Flat IP may streamline network design for certain applications, it can present scalability challenges in larger networks. The scheme requires a substantial pool of unique identifiers and lacks a structured hierarchy, potentially reducing efficiency for large-scale networks compared to traditional IP models. Nonetheless, Flat IP is a practical choice in scenarios where simplicity and direct device access are priorities.

Flat IP architecture

[edit]

This architecture is suitable for small businesses, home networks, and mobile broadband network operators because it simplifies network management and provides a direct link for real-time data applications.[1]

Overview

[edit]

Wireless operators use Flat IP architecture to address the growing need for real-time data applications delivered over mobile broadband networks. This approach moves away from traditional hierarchical network designs, favoring a simplified, horizontal structure.

Benefits of Flat IP Architecture

[edit]

Flat IP architectures offer several advantages, including:

  1. Cost Efficiency: Flat IP networks reduce reliance on specialized network hardware, such as ATM switches and MPLS routers, by utilizing a single level of communication. This approach lowers both hardware and maintenance costs.
  2. Improved Scalability and Flexibility: The absence of hierarchical layers simplifies the integration of new devices and services, benefiting mobile network operators in rapidly changing technological environments.
  3. Reduced Latency: By minimizing network layers and simplifying packet processing, flat IP architectures support latency-sensitive applications, such as Voice over IP (VoIP) and video streaming.[1]

In mobile networks, centralized anchors act as performance bottlenecks. Flat, distributed architectures avoid this by not having centralized components, thereby reducing latency and allowing for scalability and flexibility.[2]

Drawbacks and Challenges

[edit]

Despite their benefits, Flat IP architectures present several challenges:

  1. Lack of Redundancy: Flat networks rely on a single switch or point of failure, making them vulnerable to outages if that switch fails.
  2. Difficult Troubleshooting: The simplicity of flat networks can complicate troubleshooting. With fewer hierarchical layers to isolate issues, identifying the root cause of network problems can be time-consuming.
  3. Increased Security Risks: Flat networks are more vulnerable to lateral attacks, where malware or intrusions can spread quickly between devices without traditional segmentation.

Use Cases of Flat IP Architecture

[edit]

Flat IP architecture is particularly relevant to mobile networks and is supported by several industry standards organizations, including:

  1. 3rd Generation Partnership Project (3GPP) and 3GPP2: These organizations develop global standards for mobile telecommunication systems and have adopted flat IP principles in their network designs.
  2. WiMAX Forum: The WiMAX Forum, responsible for promoting and certifying wireless broadband technologies, was one of the early adopters of IP-centric mobile networks.

Key Considerations for Mobile Networks

[edit]

In mobile networks, flat IP architectures integrate the following components:[3]

  1. Advanced Base Stations: Modern base stations in flat IP networks handle multiple functions, including radio control, header compression, encryption, call admission control, and policy enforcement. These stations often use IP/Ethernet interfaces to simplify network architecture and reduce latency.
  2. Direct Tunnel Architecture: In this configuration, user data bypasses the Serving GPRS Support Node (SGSN) on the user plane. Direct Tunnel Architecture, supported by major vendors, reduces latency and complexity. Nokia-Siemens' Internet High-Speed Packet Access (IHSPA) takes this further by removing the Radio Network Controller (RNC) from the data path, resulting in even lower latencies.
  3. WiMAX Access Services Network (ASN): WiMAX was the first standardized IP-centric mobile network architecture. Although HSPA and LTE networks have since become dominant, many principles from WiMAX ASN remain relevant in modern mobile networks.

See also

[edit]

References

[edit]
  1. ^ a b Tripathy, Susnigdha (2023-02-21). "What Is a Flat Network? Definition, Benefits & How It Works". Enterprise Networking Planet. Retrieved 2024-09-26.
  2. ^ Bokor, László; Faigl, Zoltán; Imre, Sándor (2011). Flat Architectures: Towards Scalable Future Internet Mobility. Springer, Berlin, Heidelberg. ISBN 978-3-642-20898-0. Retrieved 25 November 2024.
  3. ^ "What Is A Flat Network? - ITU Online". 2024-06-11. Retrieved 2024-09-26.
[edit]
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