Abstract: Systems and methods are disclosed for hash-based selection of network packets for packet flow sampling in network communication systems. Input packets associated with packet flows within a network communication system are received by a hash-based sampler. The hash-based sampler then generates hash values for the input packets based upon fields within the input packets. These fields are selected to identify packet flows for the input packets. The hash values for the input packets are then compared to a mask. The mask is configured to determine a subset of packet flows for which to forward packets. Based upon this comparison, certain input packets are selected to be forwarded for further processing, and non-selected packets are discarded. The further processing can include processing the selected input packets to generate flow statistics data (e.g., IPFIX) for the selected input packets.

Abstract: A method of setting up a wireless connection for a communication device. The method is performed in a network node and comprises receiving, from the communication device, a service request, the request comprising a destination identifier of a destination providing a service, and configuring, based on the destination identifier, the communication device for one of: multi-connectivity and single-connectivity.

Abstract: The present invention relates to an antenna comprising multiple array elements with a first and second feeding point, each associated with orthogonal polarizations, each array element has a first and second phase centre each associated with the orthogonal polarizations, the first and second phase centres of said array elements are arranged in at least two columns, and one antenna port connected to the first and second feeding points of at least two array elements with first phase centre and second phase centre arranged in the at least two columns via a respective feeding network. The feeding network comprises a beam forming network having a primary connection, connected to the antenna port, and at least four secondary connections. The beam forming network divides power between the first feeding point and the second feeding point and controls phase shift differences between the respective feeding points with phase centre arranged in different columns.

Abstract: The disclosure provides methods in a network node for a telecommunications network. In one method, the network node operates as a primary network node for a wireless terminal configured with dual connectivity, and the method comprises: receiving a message indicating that a secondary network node, which provides user plane connectivity for the wireless terminal, has no data to transmit to the wireless terminal; and based at least in part on the received message, configuring the wireless terminal in an inactive mode.

Abstract: Traffic differentiator systems for network devices and related methods are disclosed that include automatic port order determination. The disclosed embodiments includes input ports that receive a first stream of packets and a second stream of packets and a packet difference processor that operates in a learning mode and a normal mode. In the learning mode of operation, the packet difference processor automatically determines a port order representing whether the first stream of packets for the first port or the second stream of packets for the second port represents a first in time version of received packets. In the normal mode of operation, the packet difference processor uses the port order determination to facilitate determination of difference packets between the first stream of packets and the second stream of packets.

Abstract: A system and method is introduced for flexible user equipment (“UE”) identification. In one embodiment, the method includes providing a first message from a user equipment (110) to a radio access node (120) to resume a passive user equipment context. The message includes a UE identifier (400) having a flag (410) indicating if the user equipment (110) is resuming connectivity to the radio access node (120) and a first local UE identifier (420) for the radio access node (120).

Abstract: Embodiments disclosed herein are directed towards systems and methods for electric current leakage detection in a land seismic system. Embodiments may include generating at least one test signal using a digital to analog converter “DAC” circuitry, wherein the DAC circuitry includes an output operatively connected to earth ground. Embodiments may further include alternately grounding a positive path to an analog to digital converter “ADC” circuitry during a first time window and a negative path to the analog to digital converter during a second time window while measuring an ADC signal. Embodiments may also include determining an average amplitude of the first time window and the second time window and determining a leakage resistance based upon, at least in part, the average amplitude of the first time window and the second time window.

Abstract: A technique for providing multiple connectivity to a terminal device by at least a first Radio Access Network, RAN entity and a second RAN entity is disclosed. The first RAN entity serves as a control plane anchor and the split bearer will be anchored at the second RAN entity. The method comprises triggering, by the first RAN entity, the second RAN entity to set up the split bearer on the user plane. The split bearer comprises at least a first bearer leg from the second RAN entity via the first RAN entity to the terminal device and a second bearer leg from the second RAN entity to the terminal device without going through the first RAN entity.

Abstract: A method for evaluating a connection between a first network node and a User Equipment (UE) via a second cell. The first network node serves a first cell. A sending of a first message is initiated. The first message is sent from the first network node to the UE via the second cell. The first message comprises a trigger for the UE to respond by sending a second message comprising feedback relating to the connection to the second cell. A time value difference between the sending of said first message and receiving of said second message in the first network node is obtained. The second message comprises the feedback relating to the connection sent from the UE in response to the first message. Then it is evaluated how the connection shall be used based on the obtained time value difference and the received feedback.

Abstract: Pre-sorter systems and methods are disclosed for distributing GTP packets. The pre-sorter forwards GTP packets based upon entries within one or more pre-sort tables, and the entries associate F-TEIDs with output ports that can be coupled to GTP sessions controllers and/or other external systems. The F-TEIDs represent a combination of a destination IP address and a tunnel endpoint identifier (TEID) for each GTP packet. For some embodiments, GTP session controllers analyze the GTP packets and determine F-TEIDs that are created, modified, and/or dropped for user sessions, and the GTP session controllers send control messages to the pre-sorter to determine the entries stored within the pre-sort table(s). For other embodiments, other external systems such as network monitoring tools are coupled to the GTP packet pre-sorter rather than GTP session controllers. Pre-sorters having multiple pre-sort modules with local pre-sort tables, as well as two-stage pre-sort architectures, can also be used.

Abstract: Embodiments disclosed herein are directed towards systems and methods for electric current leakage detection in a land seismic system. Embodiments may include generating at least one test signal using a digital to analog converter “DAC” circuitry, wherein the DAC circuitry includes an output operatively connected to earth ground. Embodiments may further include alternately grounding a positive path to an analog to digital converter “ADC” circuitry during a first time window and a negative path to the analog to digital converter during a second time window while measuring an ADC signal. Embodiments may also include determining an average amplitude of the first time window and the second time window and determining a leakage resistance based upon, at least in part, the average amplitude of the first time window and the second time window.

Abstract: A system and method is introduced for flexible user equipment (“UE”) identification. In one embodiment, the method includes providing a first message from a user equipment (110) to a radio access node (120) to resume a passive user equipment context. The message includes a UE identifier (400) having a flag (410) indicating if the user equipment (110) is resuming connectivity to the radio access node (120) and a first local UE identifier (420) for the radio access node (120).

Abstract: The present disclosure relates to a method in a radio access controller in a first radio access network for providing access control in a wireless network comprising the first radio access network arranged to operate according to a first radio access technology and a second radio access network arranged to operate according to a second radio access technology. The method comprises the steps of receiving an access request (Si3, Si4) originating from a wireless device, said access request comprising wireless device related information including information related to a global cell identity; assessing (P4) the access request based on the received wireless device related information, a throughput related value for the first radio access technology and a throughput related value for the second radio access technology, and responding (Si5, Si6) to the access request based on the assessment.

Abstract: Systems and methods are disclosed for hash-based selection of network packets for packet flow sampling in network communication systems. Input packets associated with packet flows within a network communication system are received by a hash-based sampler. The hash-based sampler then generates hash values for the input packets based upon fields within the input packets. These fields are selected to identify packet flows for the input packets. The hash values for the input packets are then compared to a mask. The mask is configured to determine a subset of packet flows for which to forward packets. Based upon this comparison, certain input packets are selected to be forwarded for further processing, and non-selected packets are discarded. The further processing can include processing the selected input packets to generate flow statistics data (e.g., IPFIX) for the selected input packets.

Abstract: According to an aspect, there is provided a method of operating a first radio access node in a communication network, the first radio access node supporting a plurality of cells that are divided into one or more groups of cells, wherein at least a first group of cells comprises more than one cell, the method comprising determining (901) a first base key for a communication device that is to connect to the first radio access node via a first cell in the first group of cells; wherein the first base key is determined from an identifier for the first group of cells; using (903) the first base key to determine a first encryption key that is to be used to encrypt communications between the communication device and the first radio access node via the first cell; and in the event that the communication device is to connect to the first group of first radio access node via a second cell in the first group of cells, using (907) the first encryption key to encrypt communications between the communication device and the

Abstract: The present disclosure relates to methods and an identity mediator node for controlling a user equipment, UE, identity, ID, dependent service in a radio base station, RBS of a wireless network. The method comprises receiving (S1) from a Mobility Management Entity, MME, a UE ID report comprising a permanent UE ID, a temporary UE ID, and a serving RBS identity for an RBS serving the UE, wherein the temporary UE ID represents an identifier for the UE in the serving RBS. The identity mediator node stores (S2) a record associating the temporary UE ID, the serving RBS identity, and the permanent UE ID record. When an order to activate a UE ID dependent service for a permanent UE ID is detected (D1) in the identity mediator node, the identity mediator node retrieves (S4) the temporary UE ID and serving RBS identity from the stored record. A request is sent (S5) to the serving RBS to activate the UE ID dependent service for the UE, wherein the request includes the temporary UE ID.

Abstract: Systems and methods are disclosed for hash level load balancing for removal of duplicate network packets to form deduplicated packet streams. Hash values for input packets are used in part to select deduplication engines to receive hash data associated with received input packets, and this hash data is then forwarded to the selected deduplication engines for deduplication processing. The hash level load balancing reduces bandwidth requirements within the deduplication processing as compared to prior packet-based load balancing solutions for deduplication systems. Additional embodiments utilize port identifiers in addition to hash values to allow for increased flexibility in deduplication of packets from multiple input ports.

Abstract: The present disclosure presents a method and a network entity for load contribution distribution in a wireless communication system supporting component carrier communication. The network entity serves a first cell of a wireless communication system. The method comprises receiving (61) information on one or more secondary cell usages of the first cell, wherein a secondary cell usage represents a secondary component carrier load of a wireless device connected to a primary cell of one or more further cells which are different from the first cell. The information on primary cell usage and the one or more secondary cell usage for the first cell is compiled (62) in the network entity. The method further comprises identifying (63) the respective primary cell for each secondary cell usage. Finally it comprises sending (64) secondary cell usage information to a respective network entity serving the identified respective primary cell for each secondary cell usage.

Abstract: A method in a network node for handling evaluation of a secondary cell for a wireless device. The method comprises establishing a first level of coverage of the secondary cell, based on a first measurement report received from the wireless device, which first measurement report relates to a quality of a signal of the secondary cell. The method further comprises determining an evaluation frequency, based on the established first level of coverage of the secondary cell, which evaluation frequency relates to how frequently a level of coverage of the secondary cell shall be evaluated. The method further comprises sending a configuration to the wireless device, which configuration relates to an evaluation of a second level of coverage of the secondary cell, and which configuration is based on the determined evaluation frequency.

Abstract: A method in a radio network node for determining whether a wireless device is a suitable candidate for handover to a target cell for load balancing reasons. The radio network node serves a source cell. The method includes determining a first level of coverage of the target cell based on a first measurement report. The method further includes storing measurement data obtained from a second measurement, being at least one of a layer 2 and a layer 1 measurement. The method further includes establishing a correlation between the determined first level of coverage and the stored measurement data and updating statistical data based on the established correlation. The method further includes determining whether the wireless device is a suitable candidate for handover to the target cell for load balancing reasons, based on the updated statistical data.