Abstract: The proposed technology relates to the procedure of generating a Fast Initial Link Setup, FILS, Discovery frame (1400) including Mobility Domain information (1401) and/or the exchange of such a frame between a network node and a wireless communication device, e.g. to enable the wireless communication device to determine whether to associate with the network node through a full authentication procedure or through a reduced authentication procedure.

Abstract: There is provided a method for controlling different parts of a terminal that are able to communicate over at least a first radio access technology protocol and a second radio access technology protocol, where said first and second radio access technology protocols are different and wherein said method includes the steps of detecting (1301) in logical parts that operate a first radio access technology protocol that at least parts of a second radio access technology protocol should be activated or deactivated; transmitting (1303) an indication from logical parts that operates a first radio access technology protocol to logical parts that operates a second radio access technology protocol where said indication is an input to said logical parts that operate the second radio access technology protocol to activate or deactivate parts of second radio access technology protocol.

Abstract: WI-FI/3GPP access selection techniques are used to control selection by a user terminal between cellular network cells and WI-FI cells. Cellular network cells providing overlapping coverage with WI-FI cells are correlated with the WI-FI cells. A received signal strength threshold is determined for each WI-FI cell based on an average throughput of the cellular network cells correlated with the WI-FI cell. The WI-FI user terminal admit threshold is used to control the effective coverage of the WI-FI cell. A user terminal operating within a cellular network cell is admitted to a WI-FI only if it is within the effective coverage area of the WI-FI cell as determined by the received signal strength threshold. Increasing the threshold shrinks the effective coverage area of the WI-FI cell to allow user terminal only of strong RSSI to make connection to the cell, and steers user terminal of weak RSSI away from the WI-FI cell.

Abstract: There is provided a method of operating a terminal in a first network that is operating according to a first radio access technology, RAT, the method comprising receiving (171) a message from the first network, the message being for configuring the terminal with a set of criteria for enabling, detecting and/or performing measurements over a second RAT; determining (173) if the set of criteria in the message are fulfilled by a network operating according to a second RAT; and steering (175) all or a subset of the traffic for the terminal to the network operating according to the second RAT if the set of criteria are fulfilled.

Abstract: WI-FI/3GPP access selection techniques are used to control selection by a user terminal between cellular network cells and WI-FI cells. Cellular network cells providing overlapping coverage with WI-FI cells are correlated with the WI-FI cells. A received signal strength threshold is determined for each WI-FI cell based on an average throughput of the cellular network cells correlated with the WI-FI cell. The WI-FI user terminal admit threshold is used to control the effective coverage of the WI-FI cell. A user terminal operating within a cellular network cell is admitted to a WI-FI only if it is within the effective coverage area of the WI-FI cell as determined by the received signal strength threshold. Increasing the threshold shrinks the effective coverage area of the WI-FI cell to allow user terminal only of strong RSSI to make connection to the Cell, and steers user terminal of weak RSSI away from the WI-FI cell.

Abstract: A method and a wireless access node for enabling management of cellular connectivity of a wireless device as well as a method and a wireless device for providing information about availability of cellular connectivity towards a radio network node are disclosed. The wireless device has Wi-Fi radio for access to the wireless access node and cellular radio for access to the radio network node. The wireless device sends, to the wireless access node, a second message, which indicates to the wireless access node availability of the cellular connectivity. The wireless access node manages the cellular connectivity based on the second message.

Abstract: A method and apparatus for determining whether to allow attachment of a mobile terminal to a Radio Access Network. A selection function node receives an indication that the mobile terminal has requested to attach to the Radio Access Network. A determination is made of a property of a radio connection on both an uplink and a downlink between the mobile terminal and the RAN. On the basis of the determined property, a further determination is made as to whether to allow attachment of the mobile terminal to the RAN.

Abstract: A method of operation of a network of WLAN access points comprises establishing a first WLAN access point (APa) having a first coverage area; and establishing a plurality of second WLAN access points (AP1, . . . , AP7) having respective second coverage areas, such that the second access points provide traffic connections for at least one communications device in at least one of the respective second coverage areas; wherein the first coverage area overlaps the plurality of second coverage areas, and wherein the first WLAN access point provides control information for the at least one communications device.

Abstract: Described herein are a number of steps, methods and/or solutions that can be applied to greatly improve attenuation control of RF signals in cable plant. The present disclosure is directed to a cable modem auto-attenuation system or any other signal transferring system. The system may be capable of taking a high-power signal from the cable plant's service line, dropping the power value down to a usable level and transmitting the signal to a cable modem while eliminating the need for rigorous manual adjustments that a normal cable modem often requires. In certain embodiments, the system may be integrated into a separate device connected between the modem and the cable company service line and configured to handle upstream and downstream attenuation separately or jointly.

Abstract: Methods and apparatus are disclosed for steering UEs (103) connected to a first access point (102) in a WLAN (105) to either a cellular network (106) or a second access point in the WLAN network (105) having a coverage area overlapping the coverage area of the first access point (102). After determining a need to steer traffic for one or more UEs (103) to the cellular network (106) or the second AP, the first AP (102) lowers the transmit power of frames transmitted by the first AP (102) to effectively shrink the size of the first AP's coverage area causing the affected UEs (103) to reselect the cellular network (106) or the second AP to maintain service.

Abstract: The present disclosure provides a method and apparatus to initiate a session with a packet gateway for a connecting device configured to authenticate with a subscribing wireless device's authentication information. In some embodiments, an access node is configured to receive identification information uniquely identifying the connecting device, and based on the identification information received, provide a service to the connecting device and/or send a session request message to the packet gateway to establish a session for the connecting device, the session request message including information distinguishing the connecting device from another wireless device configured to authenticate with the authentication information associated with the subscribing wireless device.

Abstract: A high performance wireless mesh architecture which has been optimized for mobile end points is described. The mesh architecture is intended for Navy applications, where the wireless mesh network extends between mobile ships and includes ship-to-shore links, but it is equally applicable to other mobile elements on, in, or under land, air, sea, or space.

Abstract: A high performance wireless mesh architecture which has been optimized for mobile end points is described. The mesh architecture is intended for Navy applications, where the wireless mesh network extends between mobile ships and includes ship-to-shore links, but it is equally applicable to other mobile elements on, in, or under land, air, sea, or space.

Abstract: A method and apparatus are disclosed for steering a UE (103) from a WLAN (105) to a cellular network (106) with an overlapping coverage area. The UE (103) is connected to the WLAN (105) through an access point (AP) (102). The AP (102) suppresses the broadcast of a network identifier of the WLAN (105) and de-authenticates the UE (103) from the WLAN (105). After de-authenticating the UE (103), the AP (102) ignores probe requests from the UE (103). The UE (103) will conclude that the WLAN (105) is no longer available and will connect to the cellular network. From the perspective of the UE (103), the suppression of the network makes it appear to the UE (103) that it has moved out of range of the AP (102) so the UE (103) will not “blacklist” the WLAN (105). The suppression of the network ID will not impact UEs not targeted, which will continue to communicate via WLAN (105) even when the network ID is suppressed.

Abstract: WiFi/3GPP access selection techniques are used to control selection by a user terminal between cellular network cells and Wi-Fi cells. Cellular network cells providing overlapping coverage with Wi-Fi cells are correlated with the Wi-Fi cells. A received signal strength threshold is determined for each Wi-Fi cell based on an average throughput of the cellular network cells correlated with the Wi-Fi cell. The WiFi user terminal admit threshold is used to control the effective coverage of the Wi-Fi cell. A user terminal operating within a cellular network cell is admitted to a Wi-Fi only if it is within the effective coverage area of the Wi-Fi cell as determined by the received signal strength threshold. Increasing the threshold shrinks the effective coverage area of the Wi-Fi cell to allow user terminal only of strong RSSI to make connection to the WiFi Cell, and steers user terminal of weak RSSI away from the Wi-Fi cell.

Abstract: Multi-beam smart antenna for WLAN and cellular applications preferably has a steerable antenna system with a dipole antenna element located at the center of a ground plane. A first conductor is oriented parallel and collinear with a second conductor, and the ground plane is located therebetween. Each of first parasitic elements is positioned substantially parallel to the dipole element, and arranged on the upper-side of the ground plane in an array. Each of second parasitic elements is positioned parallel to the dipole element, and arranged on the underside of the ground plane in the same predetermined array. A plurality of switching elements connect parasitic elements and the ground plane to form reflective elements. Each parasitic element and corresponding parasitic element are oriented parallel and collinear with each other. A switching controller controls the switching elements to alter the antenna system's beam pattern by selectively activating or deactivating the reflective elements.

Abstract: Systems and methods are disclosed for providing a network-instructed handover of a wireless device from a Wireless Local Area Network (WLAN) to a Radio Access Network (RAN) of another Radio Access Technology (RAT), e.g., a 3rd Generation Partnership Project (3GPP) or 3rd Generation Partnership Project 2 (3GPP2) RAT. In one embodiment, a WLAN access node determines that a handover of a wireless device from the WLAN to another RAN of a different RAT is to be performed and transmits a handover instruction to the wireless device that instructs the wireless device to perform a handover from the WLAN to a RAN of a different RAT. In this manner, the WLAN access node is able to steer the wireless device from the WLAN to a RAN of a different RAT.

Abstract: A fringe-effect vault antenna includes a communications vault having a non-conductive cover disposed substantially at ground level. An antenna element is positioned in the communications vault. A metallic reflector has an edge, positioned substantially parallel to the ground, where the metallic reflector and the edge are configured to cause an edge diffraction, or “fringe-effect” upon the RF fields of the antenna to cause those RF fields to diffract in a direction toward the ground.

Abstract: A wireless network system is provided. The system comprises a wireless network controller and a plurality of access points and/or femtocells. The wireless network controller is in communication with each of the plurality of access points and/or femtocells via an access data network, and is configured to perform one or more network control functions for the benefit of the plurality of access points and/or femtocells. The network control functions may be selected from management and operation, client authentication, mobility, and per-user administration. The wireless network controller is remotely located and operated with respect to the plurality of access points and/or femtocells.

Abstract: A system for improving TCP signal reception comprising a TCP-relay component, a wireless component and an antenna (e.g., a smart antenna) coupled to the wireless component. The system being configured to receive a TCP packet with sequence number “N”, send that packet wirelessly (e.g., using 802.11) to a client, receive the client's wireless ACK indicating that the packet was received, and use the client's ACK as the trigger to send a TCP-Acknowledgement of the TCP sequence number “N”.