Cisco Cisco Packet Data Gateway (PDG)
In HeNB-GW service implementation, the contexts can be classified into source or destination contexts. This
is because GTP-U tunnels as well as HeNB-GW Access and Network services can be created over a single
context.
is because GTP-U tunnels as well as HeNB-GW Access and Network services can be created over a single
context.
The IP addresses as well as interfaces can also under the defined under the same context. These IP addresses
are later used to bind with different services including GTP-U, MME and Interfaces including S1-MME for
HeNB-GW Access service and Network service.
are later used to bind with different services including GTP-U, MME and Interfaces including S1-MME for
HeNB-GW Access service and Network service.
Logical Interfaces
This section describes the logical interface supported on HeNB-GW.
Prior to allowing the flow of user data, the port must be associated with a virtual circuit or tunnel called a
logical interface. A logical interface within the system is defined as the logical assignment of a virtual router
instance that provides higher-layer protocol transport, such as Layer 3 IP addressing. Interfaces are configured
as part of the VPN context and are independent from the physical port that will be used to bridge the virtual
interfaces to the network.
logical interface. A logical interface within the system is defined as the logical assignment of a virtual router
instance that provides higher-layer protocol transport, such as Layer 3 IP addressing. Interfaces are configured
as part of the VPN context and are independent from the physical port that will be used to bridge the virtual
interfaces to the network.
Logical interfaces are assigned to IP addresses and are bound to a specific port during the configuration
process. Logical interfaces are also associated with services through bindings. Services are bound to an IP
address that is configured for a particular logical interface. When associated, the interface takes on the
characteristics of the functions enabled by the service. For example, if an interface is bound to an HeNB-GW
service, it will function as an S1-MME interface between the HeNB-GW/SeGW service and MME. Services
are defined later in this section.
process. Logical interfaces are also associated with services through bindings. Services are bound to an IP
address that is configured for a particular logical interface. When associated, the interface takes on the
characteristics of the functions enabled by the service. For example, if an interface is bound to an HeNB-GW
service, it will function as an S1-MME interface between the HeNB-GW/SeGW service and MME. Services
are defined later in this section.
In support of both mobile and network originated subscriber UE contexts, the HeNB-GW provides the following
network interface support:
network interface support:
• S1 Interface: This interface is the reference point for the control plane protocol between Home eNodeB
and HeNB-GW. This interface sets up S1AP association over SCTP as the transport layer protocol for
guaranteed delivery of signaling messages between HeNB-GW and Home eNodeB.
This is the interface used by the HeNB-GW to communicate with HeNBs on the same Femtocell Access
Network. This interface serves as path for establishing and maintaining subscriber UE contexts.
guaranteed delivery of signaling messages between HeNB-GW and Home eNodeB.
This is the interface used by the HeNB-GW to communicate with HeNBs on the same Femtocell Access
Network. This interface serves as path for establishing and maintaining subscriber UE contexts.
• S1-MME Interface: This interface is the reference point for the control plane protocol between E-UTRAN
and MME in the LTE Femtocell network.
Protocol stack architecture for the S1-MME interface has been described in the Protocol Architecture
section of the Overview chapter of this guide.
Protocol stack architecture for the S1-MME interface has been described in the Protocol Architecture
section of the Overview chapter of this guide.
The Stream Control Transmission Protocol (SCTP) guarantees the delivery of signalling messages
between MME and eNodeB via HeNB-GW.
between MME and eNodeB via HeNB-GW.
• S1-U: This interface is the reference point between E-UTRAN and Serving Gateway (S-GW). This
interface is responsible for the per bearer user plane tunnelling and inter eNodeB path switching during
handover.
The HeNB-GW functions as a user-plane concentrator along with the control-plane concentration
function. This allows the S-GW to view the cluster of femtocells as a single entity. The user-plane
aggregation functionality provides support to GTP-U.
handover.
The HeNB-GW functions as a user-plane concentrator along with the control-plane concentration
function. This allows the S-GW to view the cluster of femtocells as a single entity. The user-plane
aggregation functionality provides support to GTP-U.
• RADIUS: This interface is the reference point between a Security Gateway (SeGW) and a 3GPP AAA
Server or 3GPP AAA proxy (OCS/CGF/AAA/HSS) over RADIUS protocol for AAA procedures for
Femto user.
Femto user.
HeNB-GW Administration Guide, StarOS Release 19
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Understanding the Service Operation
Logical Interfaces