Rajib Taid

Mobile Communications Systems Development


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29.280, 23.401, 36.413

Schematic illustration of interworking of LTE/EPS with GERAN and UTRAN through legacy network elements.

      Source: © 2015. 3GPP ™ TSs and TRs are the property of ARIB, ATIS, CCSA, ETSI, TSDSI, TTA and TTC who jointly own the copyright in them. © 2015, 3GPP.

      In Figure 6.10, only the representative figure for the GERAN and UTRAN networks along with the legacy SGSN is shown. The Gn interface works on top of the GTP and is used by the legacy GPRS and UMTS SGSN to communicate with the GGSN of a GPRS and UMTS network. The LTE/EPC MME communicates with the legacy SGSN over the Gn interface. LTE/EPC S‐GW also interfaces with the legacy SGSN through the Gn interface. The EPC HSS communicates with the SGSN through the existing Gr interface that works on top of the SS7 signaling protocols. On the other hand, the HSS communicates with the MME through the S6a interface that works on top of IP transport.

      In the previous section, interworking among the legacy systems has been described. To support seamless mobile communications services to subscribers during the inter‐system movement, the 5G system also provides interworking capabilities to operators. However, the 5G system supports interworking with the LTE/EPS only. For interworking between the 5G system and the LTE/EPS, the 3GPP defines a new inter core networks logical interface called N26 between the Access and Management Function (AMF) in 5G core network and the MME in the LTE/EPC network. It may be noted that interworking between the LTE/EPS and the 5G system can also take place without the presence of the N26 interface. Further, depending on the availability of the N26 interface between the 5GC/AMF and LTE/EPS MME for interworking between them, a UE can operate in one of the following modes:

       Single Registration Mode, where the N26 logical interface is available between the 5GC/AMF and LTE/EPS MME.

       Dual Registration Mode, where the N26 logical interface is not available between the 5GC/AMF and LTE/EPS MME.

      Interworking between the 5G and the LTE/EPS with or without the N26 logical interface shall be described later in Chapter 16.

      The roaming capability of a mobile communications network makes it possible to offer seamless voice and data services by a network operator to its subscribers while traveling outside of their home network and location and enter into a network that is run by the same or different operator in a different location. Roaming services are delivered to subscribers through the interoperation of networks operated by the same or another operator. Interoperation, in turn, is achieved through the interworking of network elements and interfaces as described in the previous sections.

      In the previous Sections 6.2 and 6.3, we have presented the interworking of the GSM, GPRS UMTS, and LTE/EPS networks, through the enhanced as well as legacy network elements, run by an operator. In this section, we further present the interoperations and interworking of mobile communications networks operated by different operators in different regions to provide roaming services to subscribers.

      A mobile communications network operated by an operator to provide communications services in a particular area/location is known as the Public Land Mobile Network (PLMN). A PLMN is uniquely identified, also see Section 5.2, by the combination of an MCC and MNC of an operator. Within a PLMN, an operator may provide both the voice (CS) and data services to subscribers. The PLMN in which an MS/UE is currently subscribed and registered in an LTE/EPS network is known as the home PLMN (HPLMN). The PLMN of either the same or different operator in which an MS/UE is currently roaming into and accessed the visited LTE/EPS network is known as the visiting PLMN (VPLMN).

      6.5.1 Roaming Through Interoperations of Enhanced Networks Elements

      In this interoperation and roaming scenario, the enhanced network elements for the LTE/EPS network are deployed both in the HPLMN and the VPLMN. There are two ways to transfer user data between the UE and the Internet in case of roaming between two different PLMNs with the enhanced network elements. To enable such roaming scenarios, new logical interfaces are used to interconnect among the network elements as described below:

       Routing of User Data by the HPLMN

Schematic illustration of roaming: routing of user data by the HPLMN for roaming user.

      In Figure 6.11, the thin dashed line represents the boundary that separates the HPLMN and the VPLMN. The arrow represents that the UE has left its HPLMN and registered with the VPLMN.

       Routing of User Data by the VPLMN

      Unlike the previous