Abstract: A network element is configured to receive a first packet from a first eNodeB (eNB) of the packet network via a first secured X2 link. The network element decrypts the first packet to reveal a second packet encapsulated within the first packet. The network element determines a second secured X2 link associated with a second eNB as an intended recipient of the second packet. The network element encrypts the second packet to generate a third packet and transmits the third packet to the second eNB via the second secured X2 link. The network is coupled to various eNBs of the packet network via various secured X2 links, respectively.

Abstract: According to one aspect, a multi-function gateway device (MFG) receives a request for terminating a first data session identified by a first IP address, the request originating either directly from a user equipment (UE), or indirectly from the UE via a radio access controller (RNC), wherein the UE is communicatively coupled to a 3G radio access network (RAN), such that data traffic of the first data session is routed to a first serving GPRS support node (SGSN). According to one aspect of the invention, the MFG further determines whether the UE is connected to the MFG via a WiFi RAN, any 3G call teardown related messages are blocked in order to keep the 3G GTP-U tunnel up. Continue routing user's data originating via the WiFi RAN over the GTP-U tunnel with the SGSN.

Abstract: In one embodiment, a WLAN gateway (WGW) receives a dynamic host configuration protocol (DHCP) request from a WLAN controller for an IP address of a user equipment (UE). In one embodiment, DHCP server within the WGW assigns a local IP (LIP) address to the UE from a pool of local IP addresses maintained by the DHCP server. The WGW communicates the UE LIP address to the WLAN controller, wherein the UE LIP address is used by the WLAN controller to identify traffic to/from the UE while the UE is communicatively coupled to the WLAN and exchange the DE traffic between WGW and WLAN controller. In one embodiment, the WGW is configured to perform network address translation between the UE LIP and an external IP address assigned by one or more networks of the mobile network operator (MNO) to allow the UE to reach the network(s) in addition to the Internet.

Abstract: According to one aspect of the invention, packets of a first type within a first data flow are routed to a destination through a packet core network. In response to a detection that packets of a second type are to be routed while routing the first data flow, a second data flow is created which is a sub-flow of the first data flow. Packets of the second type are routed via the second data flow to the destination without traversing the packet core network, while packets of the first type are routed via the first data flow traversing the packet core network.

Abstract: Techniques for inserting a new node into a communications path of existing nodes of a 3GPP network are described herein. According to one embodiment, state information is captured within a transport protocol layer of a first node. The state information pertains to an existing communications session between a second node and a third node, while the first node routing packets exchanged between the second and third nodes via the existing communications session. The transport protocol layer of the first node is then configured using the captured state information to enable the transport protocol layer of the first node to independently communicate with a transport protocol layer of the second node and the third node respectively without terminating the existing communications session.

Abstract: According to one aspect, a mobility gateway device (MGW) receives a request from a wireless local area network (WLAN) controller of a WLAN for accessing the Internet or a packet core network, where the request is originated from a user equipment communicatively coupled to the WLAN. In response to the request, the MGW is configured to determine whether there is an active session associated with the UE over a wireless wide area network (WWAN). If so, the MGW assigns an IP address to the UE that was assigned to the UE during the active session of the WWAN. The assigned IP address is used by the UE to access the Internet or the packet core network over the WLAN.

Abstract: Techniques for bypassing a packet core network for Internet bound traffic from user equipment (UE) via a RAN are described herein. According to one embodiment, it is determined whether a packet of data is destined for the Internet, in response to receiving the packet from a radio network controller (RNC) of a radio access network (RAN). The packet is originated from user equipment (UE) over the RAN. The packet is routed directly to the Internet without sending the packet to an SGSN (serving GPRS support node) of a packet core network, if the packet is destined to the Internet. Other methods and apparatuses are also described.

Abstract: A first packet is received at a network element from an E-UTRAN Node B (eNB) of an E-UTRAN access network via a secured communications tunnel of a secured connection, where the first packet encapsulates a second packet therein. It is determined whether the network element serves both a security gateway functionality and a serving gateway functionality of a core packet network based on the first packet and the second packet. The network element negotiates with the eNB to switch further communications from a tunnel mode to a transport mode of the secured connection if it is determined that the network element serves both the security gateway functionality and the serving gateway functionality. Thereafter, the network element exchanges further packets with the eNB via the transport mode of the secured connection after the eNB switches from the tunnel mode to the transport mode.

Abstract: A network element is configured to receive a first packet from a first eNodeB (eNB) of the packet network via a first secured X2 link. The network element decrypts the first packet to reveal a second packet encapsulated within the first packet. The network element determines a second secured X2 link associated with a second eNB as an intended recipient of the second packet. The network element encrypts the second packet to generate a third packet and transmits the third packet to the second eNB via the second secured X2 link.

Abstract: A type of network traffic associated with a packet received from a remote node of an access network is determined. A first interface logic routes the packet to a radio network controller (RNC) if the packet is received from an Internet protocol-basestation (IP-BTS) access network and destined to a packet core network. The RNC forwards the packet to a component of the packet core network. A second interface logic routes the packet to the component of the packet core network, including aggregating other packets of the same type received from other remote nodes, if the packet is received from a femto cell and destined to the packet core network. A breakout logic routes the packet to a destination of the Internet directly to enable the packet to reach the Internet without having to route the packet to the component of the packet core network, if the packet is destined to the Internet.

Abstract: A method is described that involves performing the following at an offload network gateway: receiving a RELOCATION_REQUIRED message from an RNC; recognizing that the RELOCATION— REQUIRED message pertains to a roaming device having a live session with a network that the offload network gateway acts as a gateway to in order to offload data traffic from the GPRS network; and, adding information specific to the session to the RELOCATION— REQUIRED message. A method is also described that includes performing the following at an offload network gateway: receiving a RELOCATION _REQUEST message; inspecting the RELOCATION_REQUEST message for information specific to a roaming device's live session with a network that the offload network gateway acts as a gateway to in order to offload data traffic from a GPRS network; and, in response to identifying the information within the RELOCATION— REQUEST message, extracting the information and using the information to continue the session for the roaming device.

Abstract: According to one aspect, a mobility gateway device (MGW) receives a request from a wireless local area network (WLAN) controller of a WLAN for accessing the Internet or a packet core network, where the request is originated from a user equipment communicatively coupled to the WLAN. In response to the request, the MGW is configured to determine whether there is an active session associated with the UE over a wireless wide area network (WWAN). If so, the MGW assigns an IP address to the UE that was assigned to the UE during the active session of the WWAN. The assigned IP address is used by the UE to access the Internet or the packet core network over the WLAN.

Abstract: A first packet is received at a network element from an E-UTRAN Node B (eNB) of an E-UTRAN access network via a secured communications tunnel of a secured connection, where the first packet encapsulates a second packet therein. It is determined whether the network element serves both a security gateway functionality and a serving gateway functionality of a core packet network based on the first packet and the second packet. The network element negotiates with the eNB to switch further communications from a tunnel mode to a transport mode of the secured connection if it is determined that the network element serves both the security gateway functionality and the serving gateway functionality. Thereafter, the network element exchanges further packets with the eNB via the transport mode of the secured connection after the eNB switches from the tunnel mode to the transport mode.

Abstract: According to one aspect of the invention, packets of a first type within a first data flow are routed to a destination through a packet core network. In response to a detection that packets of a second type are to be routed while routing the first data flow, a second data flow is created which is a sub-flow of the first data flow. Packets of the second type are routed via the second data flow to the destination without traversing the packet core network, while packets of the first type are routed via the first data flow traversing the packet core network.

Abstract: A type of network traffic associated with a packet received from a remote node of an access network is determined. A first interface logic routes the packet to a radio network controller (RNC) if the packet is received from an Internet protocol-basestation (IP-BTS) access network and destined to a packet core network. The RNC forwards the packet to a component of the packet core network. A second interface logic routes the packet to the component of the packet core network, including aggregating other packets of the same type received from other remote nodes, if the packet is received from a femto cell and destined to the packet core network. A breakout logic routes the packet to a destination of the Internet directly to enable the packet to reach the Internet without having to route the packet to the component of the packet core network, if the packet is destined to the Internet.

Abstract: A fluid-driven alternator for use in a downhole well bore having fluid flowing therethrough includes a housing and an internal impeller rotatably mounted in the housing. A stator and rotor are mounted within the housing, and the internal impeller is coupled to the rotor. Fluid flowing through the housing rotates the impeller which in turn rotates the rotor. A flow diverter can be provided to direct fluid into the housing.

Abstract: A data communication system is provided for communicating with an underground instrument package positioned on a drilling apparatus. The drilling apparatus has an insulated section between first and second conductive sections. The system includes a power supply connected to the first conductive section of the drilling apparatus and to the ground. A receiver measures current flowing through the power supply. An electrical path is provided between the first and second conductive sections of the drilling apparatus. A switch provided in the electrical path opens and closes the electrical path in response to the data generated by the instrument package.

Abstract: Combustion variables are diagnosed using sensors to measure turbulence in the post-flame zone as well as in the flame envelope of a combustor. Output signals from the sensors are processed and a set of statistical functions are calculated which are correlated with specific combustion variables, such as the concentration of unburned carbon in fly ash. A special sensor mounting box provides reliable long-term operation in harsh combustor environment, without a supply of cooling or protective air flow.

Abstract: In one embodiment, a gas-sensing probe for use in a combustor includes an elongated support member, a housing, a gas sensor and sensor wires. The housing is attached to an end of the support member, and the gas sensor is rigidly supported within the housing. In another embodiment, a gas-sensing probe for use in a combustor includes an elongated support member, a housing, and a gas sensor. The housing is removably attached to an end of the support member, and the gas sensor is disposed within the housing so that the gas sensor and housing are removable from the distal end of the support member as a unit. In another embodiment, a gas-sensing probe comprises an elongated support member, a gas sensor, and a calibration tube. The elongated support member has a proximal end and a distal end, and supports the gas sensor at the distal end thereof.

Abstract: A Nernstian-type gas sensor for monitoring changes in a concentration of oxygen present in an environment. One embodiment includes a mass of solid-electrolyte material, and first and second electrodes. The first and second electrodes are each in fluid communication with the environment and are arranged to generate a signal therebetween indicative of a difference between an oxygen concentration at the first electrode and an oxygen concentration at the second electrode. The sensor may be free of a temperature control device.