LTE-WLAN Aggregation

Last updated

LTE-WLAN aggregation (LWA) is a technology defined by the 3GPP. In LWA, a mobile handset supporting both LTE and Wi-Fi may be configured by the network to utilize both links simultaneously. It provides an alternative method of using LTE in unlicensed spectrum, which unlike LAA/LTE-U can be deployed without hardware changes to the network infrastructure equipment and mobile devices, while providing similar performance to that of LAA. Unlike other methods of using LTE and WLAN simultaneously (e.g. Multipath TCP), LWA allows using both links for a single traffic flow and is generally more efficient, due to coordination at lower protocol stack layers.

Contents

For a user, LWA offers seamless usage of both LTE and Wi-Fi networks and substantially increased performance. For a cellular operator, LWA simplifies Wi-Fi deployment, improves system utilization and reduces network operation and management costs. LWA can be deployed in collocated manner, where the eNB and the Wi-Fi AP or AC are integrated into the same physical device or in non-collocated manner, where the eNB and the Wi-Fi AP or AC are connected via a standardized interface referred to as Xw. The latter deployment option is particularly suitable for the case when Wi-Fi needs to cover large areas and/or Wi-Fi services are provided by a 3rd party (e.g. a university campus), rather than a cellular operator.

LWA has been standardized by the 3GPP in Release-13. Release 14 Enhanced LWA (eLWA) adds support for 60 GHz band (802.11ad and 802.11ay aka WiGig) with 2.16 GHz bandwidth, uplink aggregation, mobility improvements and other enhancements.

Background

Cellular networks have been designed for licensed spectrum. However, as usage patterns changed from voice-centric to data-centric and data usage surged, operators started looking into unlicensed spectrum opportunities. Using WLAN does not only allow operators to increase peak data rate and system capacity, but also to offer services for non-cellular devices, such as laptops.

To cater to operators demand, 3GPP have defined various methods for integrating WLAN access into operator's network deployments.

Based on how the WLAN access is integrated in the operator network there are two categories: 1) Core Network integration, in which the WLAN access is connected to the operator core network using either S2a or S2b interfaces) available in 3GPP networks since Release 8 and 2) RAN based integration in which the WLAN access is directly connected to RAN access nodes (eg. LWA or LWIP) available since Release 13. All of the above methods of integration assume a certain level of service continuity as well as the terminal devices being always under a licensed spectrum cellular coverage. When service continuity is not assumed the WLAN access it is said to be integrated through what is called Non-Seamless WLAN Offload (NSWO).

A terminal device may access either cellular or WLAN access or both. This procedure may be either network initiated or terminal initiated. When it is network initiated it may be either based on core network signaling (eg. NAS in the case of Network based IP flow mobility) or RAN based rules. Terminal based initiated procedures are based on either operator policies provided to the terminals (eg. through ANDSF), user based policies/preferences, etc. These policies may take into account various conditions (eg. time, location, network load, access load, radio conditions, etc.) in determining both the access selection as well as traffic switching from one access to another.

In LTE - WLAN Aggregation (eg. LWA or LWIP) the WLAN access is directly connected to RAN access nodes and the access selection and traffic steering/splitting is done entirely under the control of the Radio Access Network node (eg. eNB).

LWA in depth

From the network perspective, there are two options that provide flexibility when looking at deploying LWA - collocated and non-collocated. In the former, the WLAN Access Point (AP) or Access Controller (AC) is physically integrated with the LTE eNB, whereas in the latter the WLAN network (i.e. APs and/or ACs) are connected to the LTE eNB via an external network interface (Xw).

LWA design primarily follows LTE Dual Connectivity (DC) architecture [3] as defined in 3GPP Release 12, which allows a UE to connect to multiple base stations simultaneously, with WLAN used instead of LTE Secondary eNB (SeNB).

In the user plane, LTE and WLAN are aggregated at the Packet Data Convergence Protocol (PDCP) level. In the downlink, the eNB may schedule PDCP PDUs of the same bearer to be delivered to the UE either via LTE or WLAN. This is possible as the PDCP layer can re-order packets received from both LTE and WLAN links, which in its turn results in substantial performance gains. In order to perform efficient scheduling and to assign packets to LTE and WLAN links in the most efficient manner, the eNB can receive radio information about both links, including flow control indication. In order to avoid changes to the WLAN MAC, LWA uses an EtherType allocated for this purpose, so that LWA traffic is transparent to WLAN AP.

In the control plane, Evolved Node B (eNB) is responsible for LWA activation, de-activation and the decision as to which bearers are offloaded to the WLAN. It does so using WLAN measurement information reported by the UE. Once LWA is activated, the eNB configures the UE with a list of WLAN identifiers (referred to as the WLAN Mobility Set) within which the UE can move without notifying the network. This is a tradeoff between fully network controlled mobility and fully UE controlled mobility.

Even though WLAN usage in LWA is controlled by cellular network, UE has the option to "opt out" in order to use home WLAN (in case UE does not support concurrent WLAN operation). Generally, the design tries to balance between LTE technology which is traditionally network-controlled and WLAN technology, which normally allows a lot of freedom for the terminal (e.g. in terms of network selection and traffic steering). With LWA design, the high level decision (e.g. LWA activation) is performed by the network, but there is sufficient level of UE freedom and flexibility (within the limits set by the network).

The first LWA version defined in Release-14 supported downlink aggregation only. This has been further enhanced in Release-15 with uplink aggregation and support for 60 GHz band (aka WiGig).

LWA performance

Some contributions [1] use simulations of small cell deployments supporting both cellular and WLAN coverage using LWA. It shows that by using bearer split LWA improves the average as well as the cell edge user perceived throughput across all small cell users in the system when compared to the Rel-12/Rel-13 radio interworking schemes. In these schemes the WLAN is connected through the operator's core network instead of being anchored in the Radio access and the traffic may be switched from one access to another based on the radio conditions of the access including the load of the access. It is not clear though how much improvement LWA may bring when it is compared with other RAN based LTE-WLAN Aggregation solution (eg. LWIP).

Deployments

On 19 August 2016 Singapore's M1 announced [2] Singapore’s first commercial HetNet (Heterogeneous Network) rollout, including LWA. Through leading edge LTE-WiFi Aggregation (LWA) technology, M1 expects to deliver peak download speeds of more than 1 Gbit/s by 2017.

Chunghwa Telecom (CHT) will open a commercial LTE/Wi-Fi Aggregation (LWA) network on February 23, [3] making it the world's first telecom operator to launch LWA, according to CHT. LWA technology standards were approved by 3GPP in June 2016.

Related Research Articles

The Universal Mobile Telecommunications System (UMTS) is a third generation mobile cellular system for networks based on the GSM standard. Developed and maintained by the 3GPP, UMTS is a component of the International Telecommunication Union IMT-2000 standard set and compares with the CDMA2000 standard set for networks based on the competing cdmaOne technology. UMTS uses wideband code-division multiple access (W-CDMA) radio access technology to offer greater spectral efficiency and bandwidth to mobile network operators.

4G is the fourth generation of broadband cellular network technology, succeeding 3G and preceding 5G. A 4G system must provide capabilities defined by ITU in IMT Advanced. Potential and current applications include amended mobile web access, IP telephony, gaming services, high-definition mobile TV, video conferencing, and 3D television.

<span class="mw-page-title-main">Voice over WLAN</span> Use of a wireless network for the purpose of voice communication

Voice over wireless LAN (VoWLAN), also voice over Wi‑Fi (VoWiFi), is the use of a wireless broadband network according to the IEEE 802.11 standards for the purpose of vocal conversation. In essence, it is voice over IP (VoIP) over a Wi-Fi network. In most cases, the Wi-Fi network and voice components supporting the voice system are privately owned.

In telecommunications networks, RANAP is a protocol specified by 3GPP in TS 25.413 and used in UMTS for signaling between the Core Network, which can be a MSC or SGSN, and the UTRAN. RANAP is carried over Iu-interface.

Multimedia Broadcast Multicast Services (MBMS) is a point-to-multipoint interface specification for existing 3GPP cellular networks, which is designed to provide efficient delivery of broadcast and multicast services, both within a cell as well as within the core network. For broadcast transmission across multiple cells, it defines transmission via single-frequency network configurations. The specification is referred to as Evolved Multimedia Broadcast Multicast Services (eMBMS) when transmissions are delivered through an LTE network. eMBMS is also known as LTE Broadcast.

<span class="mw-page-title-main">E-UTRA</span> 3GPP interface

E-UTRA is the air interface of 3rd Generation Partnership Project (3GPP) Long Term Evolution (LTE) upgrade path for mobile networks. It is an acronym for Evolved UMTS Terrestrial Radio Access, also known as the Evolved Universal Terrestrial Radio Access in early drafts of the 3GPP LTE specification. E-UTRAN is the combination of E-UTRA, user equipment (UE), and a Node B.

Wi-Fi calling refers to mobile phone voice calls and data that are made over IP networks using Wi-Fi, instead of the cell towers provided by cellular networks. Using this feature, compatible handsets are able to route regular cellular calls through a wireless LAN (Wi-Fi) network with broadband Internet, while seamlessly change connections between the two where necessary. This feature makes use of the Generic Access Network (GAN) protocol, also known as Unlicensed Mobile Access (UMA).

Mobile VoIP or simply mVoIP is an extension of mobility to a voice over IP network. Two types of communication are generally supported: cordless telephones using DECT or PCS protocols for short range or campus communications where all base stations are linked into the same LAN, and wider area communications using 3G or 4G protocols.

The Radio Resource Control (RRC) protocol is used in UMTS, LTE and 5G on the Air interface. It is a layer 3 protocol used between UE and Base Station. This protocol is specified by 3GPP in TS 25.331 for UMTS, in TS 36.331 for LTE and in TS 38.331 for 5G New Radio. RRC messages are transported via the PDCP-Protocol.

System Architecture Evolution (SAE) is the core network architecture of mobile communications protocol group 3GPP's LTE wireless communication standard.

Proxy Mobile IPv6 is a network-based mobility management protocol standardized by IETF and is specified in RFC 5213. It is a protocol for building a common and access technology independent of mobile core networks, accommodating various access technologies such as WiMAX, 3GPP, 3GPP2 and WLAN based access architectures. Proxy Mobile IPv6 is the only network-based mobility management protocol standardized by IETF.

<span class="mw-page-title-main">LTE Advanced</span> Mobile communication standard

LTE Advanced is a mobile communication standard and a major enhancement of the Long Term Evolution (LTE) standard. It was formally submitted as a candidate 4G to ITU-T in late 2009 as meeting the requirements of the IMT-Advanced standard, and was standardized by the 3rd Generation Partnership Project (3GPP) in March 2011 as 3GPP Release 10.

Mobile data offloading is the use of complementary network technologies for delivering data originally targeted for cellular networks. Offloading reduces the amount of data being carried on the cellular bands, freeing bandwidth for other users. It is also used in situations where local cell reception may be poor, allowing the user to connect via wired services with better connectivity.

Access network discovery and selection function (ANDSF) is an entity within an evolved packet core (EPC) of the system architecture evolution (SAE) for 3GPP compliant mobile networks. The purpose of the ANDSF is to assist user equipment (UE) to discover non-3GPP access networks – such as Wi-Fi or WIMAX – that can be used for data communications in addition to 3GPP access networks and to provide the UE with rules policing the connection to these networks.

A Home eNodeB, or HeNB, is the 3GPP's term for an LTE femtocell or Small Cell.

eNodeB Mobile phone network element

E-UTRAN Node B, also known as Evolved Node B, is the element in E-UTRA of LTE that is the evolution of the element Node B in UTRA of UMTS. It is the hardware that is connected to the mobile phone network that communicates directly wirelessly with mobile handsets (UEs), like a base transceiver station (BTS) in GSM networks.

LTE-Sim is an open source framework to simulate LTE networks mainly developed by G. Piro and F. Capozzi at "Politecnico di Bari". The simulator was first presented by means of a scientific article.

Long-Term Evolution (LTE) telecommunications networks use several frequency bands with associated bandwidths.

LTE in unlicensed spectrum is an extension of the Long-Term Evolution (LTE) wireless standard that allows cellular network operators to offload some of their data traffic by accessing the unlicensed 5 GHz frequency band. LTE-Unlicensed is a proposal, originally developed by Qualcomm, for the use of the 4G LTE radio communications technology in unlicensed spectrum, such as the 5 GHz band used by 802.11a and 802.11ac compliant Wi-Fi equipment. It would serve as an alternative to carrier-owned Wi-Fi hotspots. Currently, there are a number of variants of LTE operation in the unlicensed band, namely LTE-U, License Assisted Access (LAA), MulteFire, sXGP and CBRS.

<span class="mw-page-title-main">Vehicle-to-everything</span> Communication between a vehicle and any entity that may affect the vehicle

Vehicle-to-everything (V2X) is communication between a vehicle and any entity that may affect, or may be affected by, the vehicle. It is a vehicular communication system that incorporates other more specific types of communication as V2I (vehicle-to-infrastructure), V2N (vehicle-to-network), V2V (vehicle-to-vehicle), V2P (vehicle-to-pedestrian), V2D (vehicle-to-device).

References

  1. "LTE Aggregation & Unlicensed Spectrum Archived 2015-11-06 at the Wayback Machine "
  2. "M1, Nokia announce Singapore’s first commercial nationwide HetNet rollout"
  3. "Chunghwa Telecom to launch LWA network"

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.