Abstract: A method for routing in a quantum network is provided. The method may include receiving parameters including a fidelity with coherence decay time and an entanglement generation rate for each quantum node in a mesh quantum network by a controller, the controller being configured to communicate with each quantum node of a plurality of quantum nodes in the mesh quantum network. Each quantum node includes a quantum memory and a processor. The method may also include analyzing the fidelity with coherence decay time and the entanglement generation rate to yield a determination of a path fidelity with a path coherence decay time and a path entanglement generation rate between at least one pair of quantum nodes. The method may further include, based on the determination, selecting a quantum communication path from a source node to a destination node.

Abstract: A method for routing in a quantum network is provided. The method may include receiving parameters including a fidelity with coherence decay time and an entanglement generation rate for each quantum node in a mesh quantum network by a controller, the controller being configured to communicate with each quantum node of a plurality of quantum nodes in the mesh quantum network. Each quantum node includes a quantum memory and a processor. The method may also include analyzing the fidelity with coherence decay time and the entanglement generation rate to yield a determination of a path fidelity with a path coherence decay time and a path entanglement generation rate between at least one pair of quantum nodes. The method may further include, based on the determination, selecting a quantum communication path from a source node to a destination node.

Abstract: A method for routing in a quantum network is provided. The method may include receiving parameters including a fidelity with coherence decay time and an entanglement generation rate for each quantum node in a mesh quantum network by a controller, the controller being configured to communicate with each quantum node of a plurality of quantum nodes in the mesh quantum network. Each quantum node includes a quantum memory and a processor. The method may also include analyzing the fidelity with coherence decay time and the entanglement generation rate to yield a determination of a path fidelity with a path coherence decay time and a path entanglement generation rate between at least one pair of quantum nodes. The method may further include, based on the determination, selecting a quantum communication path from a source node to a destination node.

Abstract: In one embodiment, a mobile network includes at least one Information Centric Networking (ICN) enabled mobile base station configured to support ICN transport protocol, and at least one ICN enabled evolved packet core (EPC) device configured to support ICN transport protocol, where the ICN enabled EPC device is operative to assign an ICN based identity to a user equipment (UE) according to an attach request, wherein the attach request indicates that the UE supports the ICN transport protocol.

Abstract: In one embodiment, a mobile network includes at least one Information Centric Networking (ICN) enabled mobile base station configured to support ICN transport protocol, and at least one ICN enabled evolved packet core (EPC) device configured to support ICN transport protocol, where the ICN enabled EPC device is operative to assign an ICN based identity to a user equipment (UE) according to an attach request, wherein the attach request indicates that the UE supports the ICN transport protocol.

Abstract: A method is provided in one example embodiment and includes receiving a first request from a first user equipment by a first transport layer proxy located within an access network The first request includes a request to establish a user session between the first user equipment and a remote server. The method further includes establishing a first transport layer session between the first user equipment and the first transport layer proxy, establishing a second transport layer session between the first transport layer proxy and the remote server, and establishing a first control channel between the first transport layer proxy and a transport layer function manager within a core network. The method further includes sending session state parameters associated with the first transport layer session and the second transport layer session to the transport layer function manager using the first control channel.

Abstract: In one embodiment, a mobile network includes at least one Information Centric Networking (ICN) enabled mobile base station configured to support ICN transport protocol, and at least one ICN enabled evolved packet core (EPC) device configured to support ICN transport protocol, where the ICN enabled EPC device is operative to assign an ICN based identity to a user equipment (UE) according to an attach request, wherein the attach request indicates that the UE supports the ICN transport protocol.

Abstract: In one embodiment, a mobile network includes at least one Information Centric Networking (ICN) enabled mobile base station configured to support ICN transport protocol, and at least one ICN enabled evolved packet core (EPC) device configured to support ICN transport protocol, where the ICN enabled EPC device is operative to assign an ICN based identity to a user equipment (UE) according to an attach request, wherein the attach request indicates that the UE supports the ICN transport protocol.

Abstract: In one embodiment, a mobile network includes at least one Information Centric Networking (ICN) enabled mobile base station configured to support ICN transport protocol, and at least one ICN enabled evolved packet core (EPC) device configured to support ICN transport protocol, where the ICN enabled EPC device is operative to assign an ICN based identity to a user equipment (UE) according to an attach request, wherein the attach request indicates that the UE supports the ICN transport protocol.

Abstract: In one embodiment, a method for improving content delivery for a user equipment (UE) is implemented on a computing device and includes: receiving a request from an application layer on the UE, determining whether said request is an ICN-based request using Information Centric Networking (ICN) transport protocol or an IP-based request using Internet Protocol (IP) transport protocol, and for each ICN-based request according to the determining: forwarding the ICN-based request to an ICN function on the UE, and compressing ICN headers in the ICN-based request using robust header (RoHC) compression.

Abstract: A communication method uses a distributed cell-free network of spatially independent service antennas. According to the method, pilot sequences are allocated to a user population of access terminals by an allocation procedure that imposes local relative orthogonality of pilot sequences. Channel coefficients for access terminals are determined by measuring allocated pilot sequences as received by each of the service antennas. In embodiments of the invention, the determination of channel coefficients is performed independently and the resulting channel coefficients are locally stored at the respective service antennas. At each service antenna, a processor independently uses locally stored channel coefficients to precode forward link signals or to at least partially decode reverse link signals.

Abstract: A method is provided in one example embodiment and includes receiving a first request from a first user equipment by a first transport layer proxy located within an access network The first request includes a request to establish a user session between the first user equipment and a remote server. The method further includes establishing a first transport layer session between the first user equipment and the first transport layer proxy, establishing a second transport layer session between the first transport layer proxy and the remote server, and establishing a first control channel between the first transport layer proxy and a transport layer function manager within a core network. The method further includes sending session state parameters associated with the first transport layer session and the second transport layer session to the transport layer function manager using the first control channel.

Abstract: In one embodiment, a method for improving content delivery for a user equipment (UE) is implemented on a computing device and includes: receiving a request from an application layer on the UE, determining whether said request is an ICN-based request using Information Centric Networking (ICN) transport protocol or an IP-based request using Internet Protocol (IP) transport protocol, and for each ICN-based request according to the determining: forwarding the ICN-based request to an ICN function on the UE, and compressing ICN headers in the ICN-based request using robust header (RoHC) compression.

Abstract: A method is provided in one example embodiment and includes receiving a first request from a first user equipment by a first transport layer proxy located within an access network The first request includes a request to establish a user session between the first user equipment and a remote server. The method further includes establishing a first transport layer session between the first user equipment and the first transport layer proxy, establishing a second transport layer session between the first transport layer proxy and the remote server, and establishing a first control channel between the first transport layer proxy and a transport layer function manager within a core network. The method further includes sending session state parameters associated with the first transport layer session and the second transport layer session to the transport layer function manager using the first control channel.

Abstract: The present invention provides a method of automatically configuring a base station router. The method includes modifying a transmission power for a pilot signal transmitted by the base station router. The modification of the transmission power is determined based upon a frequency of mobility-related procedure requests received by the base station router.

Abstract: A method is disclosed for routing packets in an intermediate node between a mobile node and a correspondent node in a packet-switched network, only one of said nodes being macro-mobility enabled, comprising at the intermediate node: —exchanging lower-layer-address-update-related messages with said macro-mobility enabled node; —mapping source address, destination address and potentially protocol parameters of lower-layer packets exchanged between the mobile node and the correspondent node in such a way that the macro-mobility enabled node can communicate with the other node as if the other node is also macro-mobility enabled, and such that the other node can communicate with the intermediate node as if the intermediate node is a non-macro-mobility-enabled node. Also associated devices, update methods for devices, and servers are disclosed.

Abstract: A method is provided in one example embodiment and includes receiving a first request from a first user equipment by a first transport layer proxy located within an access network The first request includes a request to establish a user session between the first user equipment and a remote server. The method further includes establishing a first transport layer session between the first user equipment and the first transport layer proxy, establishing a second transport layer session between the first transport layer proxy and the remote server, and establishing a first control channel between the first transport layer proxy and a transport layer function manager within a core network. The method further includes sending session state parameters associated with the first transport layer session and the second transport layer session to the transport layer function manager using the first control channel.

Abstract: Femto base stations and methods described herein suppress the need for an external GPS antenna and cable, while still providing a network service provider with the ability to obtain the desired GPS location coordinates and the user with the flexibility of placing the femto cell at the location of their choice within a home regardless of GPS signal strength.

Abstract: Femto base stations and methods described herein suppress the need for an external GPS antenna and cable, while still providing a network service provider with the ability to obtain the desired GPS location coordinates and the user with the flexibility of placing the femto cell at the location of their choice within a home regardless of GPS signal strength.

Abstract: A method is disclosed for routing packets in an intermediate node between a mobile node and a correspondent node in a packet-switched network, only one of said nodes being macro-mobility enabled, comprising at the intermediate node: -exchanging lower-layer-address-update-related messages with said macro-mobility enabled node; -mapping source address, destination address and potentially protocol parameters of lower-layer packets exchanged between the mobile node and the correspondent node in such a way that the macro-mobility enabled node can communicate with the other node as if the other node is also macro-mobility enabled, and such that the other node can communicate with the intermediate node as if the intermediate node is a non-macro-mobility-enabled node. Also associated devices, update methods for devices, and servers are disclosed.