Cisco Cisco ASR 5000
During dynamic P-GW node selection by HSGW, if the selected P-GW is unreachable, HSGW selects the
next P-GW entry from the P-GW candidate list returned during the S-NAPTR procedure to set up the PDN
connection. For example, when an eHRPD PDN comes up, PMIPv6 session is tried with first P-GW selected
if no reply is received for max-retransmission, HSGW tries with another P-GW if available based on DNS
resolution results by starting with initial retransmission timeout as configured. There is no limit on the number
of P-GW fallback attempts per PDN and HSGW will keep trying fallback as long as alternate P-GWs are
available. The session may, however, get dropped if session-timeout gets triggered, in which case PMIPv6
PDN will also get deleted.
next P-GW entry from the P-GW candidate list returned during the S-NAPTR procedure to set up the PDN
connection. For example, when an eHRPD PDN comes up, PMIPv6 session is tried with first P-GW selected
if no reply is received for max-retransmission, HSGW tries with another P-GW if available based on DNS
resolution results by starting with initial retransmission timeout as configured. There is no limit on the number
of P-GW fallback attempts per PDN and HSGW will keep trying fallback as long as alternate P-GWs are
available. The session may, however, get dropped if session-timeout gets triggered, in which case PMIPv6
PDN will also get deleted.
PMIPv6 Heartbeat
Proxy Mobile IPv6 (PMIPv6) is a network-based mobility management protocol to provide mobility without
requiring the participation of the mobile node in any PMIPv6 mobility related signaling. The core functional
entities Mobile Access Gateway (MAG) and the Local Mobility Anchor (LMA) set up tunnels dynamically
to manage mobility for a mobile node.
requiring the participation of the mobile node in any PMIPv6 mobility related signaling. The core functional
entities Mobile Access Gateway (MAG) and the Local Mobility Anchor (LMA) set up tunnels dynamically
to manage mobility for a mobile node.
Path management mechanism through Heartbeat messages between the MAG and LMA is important to know
the reachability of the peers, to detect failures, quickly inform peers in the event of a recovery from node
failures, and allow a peer to take appropriate action.
the reachability of the peers, to detect failures, quickly inform peers in the event of a recovery from node
failures, and allow a peer to take appropriate action.
PMIP heartbeats from the HSGW to the P-GW are supported per RFC 5847. Refer to the heartbeat command
in the LMA Service mode or MAG Service mode respectively to enable this heartbeat and configure the
heartbeat variables.
in the LMA Service mode or MAG Service mode respectively to enable this heartbeat and configure the
heartbeat variables.
For more information on PMIPv6 Heartbeat, refer to the PMIPv6 Heartbeat chapter in this guide.
Important
PPP VSNCP
VSNCP offers streamlined PPP signaling with fewer messages to reduce connection set-up latency for VoIP
services (VORA). VSNCP also includes PDN connection request messages for signaling EPC attachments
to external networks.
services (VORA). VSNCP also includes PDN connection request messages for signaling EPC attachments
to external networks.
Vendor Specific Network Control Protocol (VSNCP) provides a PPP vendor protocol in accordance with
IETF RFC 3772 that is designed for PDN establishment and is used to encapsulate user datagrams sent over
the main A10' connection between the UE and HSGW. The UE uses the VSNCP signaling to request access
to a PDN from the HSGW. It encodes one or more PDN-ID's to create multiple VSNCP instances within a
PPP connection. Additionally, all PDN connection requests include the requested Access Point Name (APN),
PDN Type (IPv4, IPv6 or IPv4/v6) and the PDN address. The UE can also include the Protocol Configuration
Options (PCO) in the VSNCP signaling and the HSGW can encode this attribute with information such as
primary/secondary DNS server or P-CSCF addresses in the Configuration Acknowledgement response message.
IETF RFC 3772 that is designed for PDN establishment and is used to encapsulate user datagrams sent over
the main A10' connection between the UE and HSGW. The UE uses the VSNCP signaling to request access
to a PDN from the HSGW. It encodes one or more PDN-ID's to create multiple VSNCP instances within a
PPP connection. Additionally, all PDN connection requests include the requested Access Point Name (APN),
PDN Type (IPv4, IPv6 or IPv4/v6) and the PDN address. The UE can also include the Protocol Configuration
Options (PCO) in the VSNCP signaling and the HSGW can encode this attribute with information such as
primary/secondary DNS server or P-CSCF addresses in the Configuration Acknowledgement response message.
Proxy Mobile IPv6 (S2a)
Provides a mobility management protocol to enable a single LTE-EPC core network to provide the call anchor
point for user sessions as the subscriber roams between native EUTRAN and non-native e-HRPD access
networks
point for user sessions as the subscriber roams between native EUTRAN and non-native e-HRPD access
networks
S2a represents the trusted non-3GPP interface between the LTE-EPC core network and the evolved HRPD
network anchored on the HSGW. In the e-HRPD network, network-based mobility provides mobility for IPv6
network anchored on the HSGW. In the e-HRPD network, network-based mobility provides mobility for IPv6
HSGW Administration Guide, StarOS Release 19
19
HRPD Serving Gateway Overview
PMIPv6 Heartbeat