Abstract: A method and apparatus for sending information are provided, herein the method for sending information includes: the sending end using a physical control channel (PDCCH) or an enhanced physical control channel (ePDCCH) or downlink control information (DCI) transmitted in the agreed resources to describe the information about time that the unlicensed carriers are occupied; the sending end sending the DCI information through licensed carriers or the unlicensed carriers; herein, the information about time includes: a starting subframe occupying an unlicensed carrier and the number of subframes that are continuously occupied starting from the starting subframe. Through the present disclosure, how to enable base stations to mutually inform about an occupation situation of the unlicensed carrier in the related art is achieved, the coordination and utilization of the unlicensed carriers in a wireless communication system are simplified the utilization rate of the unlicensed carriers is improved.

Abstract: Aspects of the subject disclosure may include, for example, a transmission device that includes at least one transceiver configured to modulate data to generate a plurality of first electromagnetic waves in accordance with channel control parameters. A plurality of couplers are configured to couple at least a portion of the plurality of first electromagnetic waves to a transmission medium, wherein the plurality of couplers generate a plurality of second electromagnetic waves that propagate along the outer surface of the transmission medium. A training controller is configured to generate the channel control parameters based on channel state information received from at least one remote transmission device. Other embodiments are disclosed.

Abstract: The present disclosure provides a wireless network coverage enhancement method, apparatus, and system. The method includes: receiving, by a terminal, a downlink signal sent by a network device; determining, by the terminal, a first coverage level of the terminal according to the downlink signal; determining, by the terminal, an uplink communications parameter according to the first coverage level; and sending, by the terminal, an uplink signal to the network device according to the uplink communications parameter. According to the method in embodiments of the present invention, a probability of successfully receiving the uplink signal is improved. Therefore, the network device does not need to send a NACK to the terminal, so that overheads of an air interface between the terminal and the network device are reduced, a period in which the terminal performs coverage enhancement is shortened, and power consumption of the terminal is reduced.

Abstract: The disclosed embodiments include methods and systems for distributing a broadband wireless signal in a building. The disclosed methods and systems feature a wireless broadband transmitter associated with multiple base antennas, where the base antennas are inserted into one or more ducts of the ventilation system of the building. Communication between the transmitter and receivers within the building may be optimized by selecting, modifying or controlling a configuration parameter of at least one of the multiple base antennas to enhance distribution of the wireless broadband signal within the ducts of the ventilation system and between the transmitter and device receivers.

Abstract: A method for operating a wireless network, wherein a base station is provided for data communication in uplink (UL) and downlink (DL) directions with at least one mobile device, includes operating the base station in a full duplex data communication mode during communication with the at least one mobile device.

Abstract: A cellular telecommunications network architecture is described where certain UEs are configured to assist the network to improve coverage in regions of poor radio conditions. In certain embodiments, appropriate UEs are selected to act as a dynamic, out-of-band coverage extensions. Network performance can thereby be improved when serving users at the cell edge (or in other poor radio condition regions of a cell).

Abstract: A passive intermodulation (PIM) tester is provided. The PIM tester includes at least one interface to couple the tester to a front-haul communication link used for communicating front-haul data to a remote radio head (RRH) having one or more antenna ports. The PIM tester includes a programmable processor, coupled to the interface, configured to execute software, wherein the software is operable to cause the tester to do the following: identify at least one tone in at least one downlink band of the remote radio head, wherein potential PIM products may appear in at least one uplink band of the remote radio head in response to the identified at least one tone; inject the identified at least one tone in the at least one downlink band of the remote radio head; and monitor the at least one uplink band for the potential PIM products from the injected at least one tone.

Abstract: According to aspects of the invention there is provided a remote unit comprising a processor and one or more terminal interfaces, the processor being connected to the one or more terminal interfaces, the terminal interfaces configured for coupling with a set of terminals, wherein the processor is configured to perform quality of service network testing using one or more of the set of terminals over one or more communication networks.

Abstract: The embodiments of the present document provide a method for processing dynamic channel detection, a station and an access point device. The method includes a station transmitting a dynamic channel detection request to an access point and the station deciding whether to use dynamic channel detection according to response information from the access point. The embodiments of the present document enable the station and the access point to negotiate whether to use a dynamic channel detection threshold. This is advantageous in finding the best balance point between improvement of channel utilization and avoidance of collision.

Abstract: Methods and apparatuses for reference signal measurement. A user equipment (UE) includes a transceiver and a processor operably connected to the transceiver. The transceiver is configured to receive reference signal (RS) resource configuration information and at least two RSs. The processor is configured to measure at least one of the at least two RSs. A first RS of the at least two RSs is non-UE-specifically configured and a second RS of the at least two RSs is UE-specifically configured.

Abstract: The present invention provides a resource controller for resource management in a telecommunication network, the telecommunication network providing a first set of resources for cellular communication and a second set of resources for direct device-to-device, D2D, communication between UEs, the resource controller comprising a measurement request unit being arranged to request a measurement be performed by at least one user equipment, the measurement indicating a capacity utilization of the second set of resources; and a resource pool adaption unit being arranged to adapt the first set of resources and the second set of resources as a function of the performed measurement. In particular, where no resources are available for D2D communication, a UE may request a bearer setup and in response suitable resources for D2D communication are provided.

Abstract: The present invention relates to a method and device for ordering the measuring of Inter-Device Interference (IDI) for a base station in a wireless communication system. In particular, the method is characterized by comprising the steps of: transmitting downlink allocation information on a certain wireless resource to a first terminal; ordering the measuring of IDI to the first terminal when the certain wireless resource is allocated for uplink communication by at least one second terminal; ordering the transmitting of a reference signal defined for measuring IDI for the at least one second terminal; and transmitting reference signal measurement information, allocated to the at least one second terminal, to the first terminal.

Abstract: A method and apparatus for performing measurements on an unlicensed carrier in a wireless communication system is provided. A user equipment (UE) receives a first unlicensed discovery reference signal (U-DRS) from a serving cell in the unlicensed carrier, performs measurement for the serving cell based on the first U-DRS, detects that reception of a second U-DRS from the serving cell is not successful, and reports a result of the measurement based on the first U-DRS.

Abstract: Separate aperiodic channel state information (CSI) reports are handled for static subframe(s), in which the direction of signal transmission is fixed, and flexible subframe(s), in which the direction of signal transmission is variable. A method by a UE includes receiving a trigger for an aperiodic CSI report as part of an uplink (UL) grant from a radio node in a static downlink (DL) subframe, where the trigger indicates a CSI subframe set, out of at least two alternative CSI subframe sets. An aperiodic CSI measurement is performed for a CSI reference resource in the indicated CSI subframe set, and the result of the CSI measurement is reported to the radio node. One of the at least two alternative CSI subframe sets relates to the one or more static subframes, and another one of the at least two alternative CSI subframe sets relates to the one or more flexible subframes.

Abstract: Dynamic application QoS profile provisioning may be provided. First, an access point may send a profile to a client device. The profile may comprise a plurality of application identifiers and a plurality policies corresponding to the plurality of application identifiers. Each of the plurality of application identifiers may respectively correspond to a plurality of applications. Next, the client device may receive the profile. Then the client device may select, from the received profile, a first policy from the plurality policies in the profile. The first policy may correspond to a first application identifier in the plurality of application identifiers. The first application identifier may correspond to a first application within the plurality of applications. The first application may be on the client device. The first application on the client device may then create a network flow from the client device to the access point based on the selected first policy.

Abstract: Disclosed herein are a method and an apparatus for a buffer status report in a mobile communication system. The method for a buffer status report includes setting a new QoS class identifier (QCI) value for supporting a radio bearer (RB) added for a low latency service; and allocating a logical channel of a RB for an existing service and a logical channel of a RB for the low latency service to logical channel groups (LCGs) in consideration of the newly set QCI value. Further the buffer status report for each logical channel performed in an LCG unit is received.

Abstract: An embodiment of the present invention may provide a method and a device for improving voice quality in a mobile communication network. An embodiment of the present invention may provide a method for improving communication quality by a base station and a device using the same, the method comprising the steps of: receiving, from a terminal, at least one internet protocol (IP)-based voice packet; determining whether a packet loss exists, on the basis of the received packet; generating compensation information corresponding to a lost packet when it is determined that a packet loss exists; and transmitting the compensation information.

Abstract: To process received wireless signals received in a receiver, a noise and interference estimate is generated by subtracting the serving cell component from the received OFDM signal, a normalized noise signal is produced by whitening the noise and interference estimate, interference information is detected from the normalized noise signal associated with corresponding reliability information indicating reliability of the interference information, interference cancellation is performed based on the interference information, and a performance indicator indicative of an accuracy of the interference cancellation is adaptively adjusted using the reliability information.

Abstract: An apparatus and a method for transmitting and/or receiving data in an electronic device are provided. According to an embodiment, an electronic device includes a communication module and a processor. When the electronic device outputs content, the processor can transmit the content to an external electronic device using the communication module, detect a state of the electronic device in relation to the output, select substitute content for the content at least based on the detection, determine a schedule corresponding to the substitute content, and transmit the substitute content to the external electronic device based on the schedule.

Abstract: The subject matter described herein relates to methods, systems, and computer readable media for test system connection resiliency. In some examples, a method for distributing monitored network traffic includes monitoring S1-MME traffic and S6a traffic in a core network of a telecommunications network. The method includes decrypting encrypted S1-MME traffic using information extracted from the S6a traffic. The method includes load balancing between a plurality of monitoring nodes using the decrypted S1-MME traffic.

Abstract: A device may detect a service condition associated with a network. The device may determine a prioritization of cells of the network based on characteristics of one or more subscribers to the cells of the network. The characteristics may include at least one of: a service type characteristic, an application type characteristic, a mobility characteristic, a vector characteristic, an altitude characteristic, a position characteristic, a location type characteristic, a device type characteristic, a device capability characteristic, a connection characteristic, a subscription characteristic, a call type characteristic, a user profile characteristic, a terrain characteristic, or an operator relationship characteristic. The device may perform an alteration to one or more network parameters based on the prioritization of cells of the network to reduce an impact of the service condition.

Abstract: Examples relate to managing network traffic. In one example, a computing device may: receive voice network traffic from each of a plurality of voice clients; enqueue the received voice network traffic into a voice Wi-Fi Multimedia (WMM) queue; determine a measure of WMM queue utilization based on data queued in the voice WMM queue; determine a measure of radio congestion for a surrounding area; and determine, based on the measure of WMM queue utilization and the measure of radio congestion, to: stop prioritization of newly received voice traffic from new voice clients, or transition at least one of the plurality of voice clients to a neighboring computing device.

Abstract: Provided is a radio base station, etc. that realize transmission control in view of QoE. According to a first aspect of the present invention, there is provided a radio base station that receives a packet(s) transmitted from a packet transmission apparatus via a network and transmits the received packet(s) to a wireless terminal(s), the radio base station including: acquisition means that acquires a packet type(s) or a packet identifier(s) set in the packet(s) by the packet transmission apparatus; and control means that performs transmission control to change a transmission order of the packet(s) based on the packet type(s) or the packet identifier(s).

Abstract: Methods and apparatus for resource allocation in the backhaul network of a radio access network are provided. Devices such as schedulers communicate utility functions to a traffic engineering controller. Each utility function expresses amount of utility associated with at least one prospective backhaul resource allocation, from the perspective of the device or clients or UEs served thereby. The traffic engineering controller incorporates the utility functions into an objective to be maximized, subject to constraints such as backhaul link capacity constraints. A backhaul resource allocation is determined by solving a corresponding optimization problem. The traffic engineering controller then instructs various entities in the backhaul network to implement the resource allocation.

Abstract: The disclosure relates to a 5G or a pre-5G communication system which will be provided to support a higher data transmission rate after a 4G communication system such as LTE.

Abstract: Upon requesting an MME (40) to handover a UE (10) to a Target MeNB (20_2), a Source MeNB (20_1) sends, to the Target MeNB (20_2) through the MME (40), information on one or more SeNBs that are candidates available for dual connectivity under control of the Target MeNB (20_2). The Target MeNB (20_2) configures a Target SeNB (30_2) that is selected based on the information to provide the dual connectivity. Alternatively, the Source MeNB (20_1) sends, to the Target MeNB (20_2), information on a Source SeNB (30_1) that has been used by the Source MeNB (20_1) for the dual connectivity. In this case, the Target MeNB (20_2) skips RRC configuration for the Source SeNB (30_1) upon the control.

Abstract: Solution for security negotiation during handover of a user equipment (UE) between different radio access technologies are provided. In the solution, the UE receives NAS security information and AS security information which are selected by the target system and then performs security negotiation with the target system according to the received NAS security information and AS security information. As such, the UE may obtain the key parameter information of the NAS and AS selected by a LTE system and perform security negotiation with the LTE system when the UE hands over from a different system, such as a UTRAN, to the LTE system.

Abstract: A method performed by a first network node of a wireless communication network for handling uplink signals sent by a UE. The wireless communication network comprises a serving network node responsible for transmitting downlink signals to the UE, and a non-serving network node capable of receiving uplink signals sent by the UE. The non-serving network node is the first network node and the serving network node is a second network node of the communication network, or vice versa. The method comprises receiving an uplink signal from the UE, measuring signal quality on the received uplink signal, and receiving signal quality information from the second network node regarding signal quality measured by the second network node on the uplink signal received by the second network node, to detect imbalances in experienced signal quality between the first network node and the second network node.

Abstract: An example method is provided in one example embodiment and may include maintaining a count of packets forwarded to a target evolved Node B (eNodeB) from a source eNodeB during a handover of a user equipment (UE) from the source eNodeB to the target eNodeB; and communicating an end marker indication message from the source eNodeB to the target eNodeB including the count of packets forwarded to the target eNodeB upon handover of the UE to the target eNodeB. A count of packets can be maintained for each bearer of the UE. A separate end marker indication message can be communicated to the target eNodeB for each bearer of the UE. The count of packets can be included in a Private Extension Information Element (IE) of the end marker indication message. In some embodiments, Radio Link Control (RLC) tuning parameters can be included in the Private Extension IE.

Abstract: An integrated radio communication system with ordered hierarchical cellular coverage comprises a first system and a second system, the coverage of the second system covered by the coverage of the first system, and a set of dual-mode terminals that can selectively use the first system or the second system. The first and second systems are configured to simultaneously share a common portion Bc of a first band B1 of frequencies respectively on a first uplink and a second uplink, and respectively manage first transmission resources and corresponding second transmission resources. The second radio communication system of lower level N2 is free to manage its second transmission resources without any coordination constraint with respect to the first system of higher level N1, whereas the first system of higher level is configured to not disturb the second system in the common frequency band portion.

Abstract: Provided is a base station that enables data communications in a small cell to continue even if a handover between macro cells occurs. In the base station (100), a handover determination unit (105) determines whether the handover of a control plane from the base station (100) to another macro cell is necessary for a terminal. If it is determined that the handover is necessary, a radio resource control unit (109) and a slave radio resource control unit (110) continue the control of a user plane communication process when the terminal is located inside a small cell, and the radio resource control unit (109) and slave radio resource control unit (110) stop the control of the user plane communication process and perform a process of handover to the other macro cell when the terminal is located outside the small cell.

Abstract: A control apparatus (151) selects a target core network entity for providing a mobility management service or a data transfer service to a radio terminal (111), from among a plurality of candidate core network entities (121, 141, 142) having different route costs to the radio terminal (111) or having different sizes of a management range, based on at least one of: a delay tolerance level of the radio terminal (111); a frequency of occurrence of control signaling of the radio terminal (111); and a communication interval of the radio terminal (111). This contributes, for example, to determining which of a plurality of core network entities is used for a radio terminal by using one or more criteria (indices or parameters) other than the mobility of the radio terminal.

Abstract: The present invention relates to a wireless communication system, and more particularly, to a method and an apparatus for processing a NAS signaling request. A method for performing a non-access stratum (NAS) signaling process by means of a terminal in a wireless communication system according to one embodiment of the present invention comprises: a step of receiving a first message that includes information indicating a network failure from a network node of a first network; a step of starting a timer relating to a network selection; and a step of selecting a second network from among network candidates excluding the first network during the operation of the timer relating to a network selection.

Abstract: Systems and methods of handling satellite channel and LTE coexistence are provided. A first device can identify at least one first frequency band. The first device can determine that at least one second frequency band of a plurality of second frequency bands overlaps with the at least one first frequency band. In response to determining that the at least one second frequency band overlaps with the at least one first frequency band, the first device transmits a message including an identifier of the first device and an indication of the at least one second frequency band to a second device. The second device receives the message. The second device, in response to receiving a channel request from the first device, allocates, from the plurality of second frequency bands, a second frequency band different from the at least one second frequency band.

Abstract: Aspects of the present disclosure describe various techniques for handling data stall in wireless local area networks (WLANs). These techniques include, for example, a method in which wireless communications are switched at a wireless station from a first network device associated with a first radio access technology (RAT) (e.g., WLAN technology) to a second network device associated with a second RAT (e.g., wireless wide area network (WWAN) technology). The wireless station may then monitor network devices associated with the first RAT, including the first network device. The wireless station may filter results from the monitoring based at least in part on one or more threshold value and identify, based on the filtered results, one of the network devices as suitable for the wireless communications. The wireless communications may then be switched at the wireless station from the second network device to the one network device identified as suitable for the wireless communications.

Abstract: Embodiments disclosed herein provide systems, methods, and computer readable media for recovering from media degradation during a communication session. In a particular embodiment, a method provides, during a communication session between a first user system operated by a first user and a second user system operated by a second user, receiving a first indication from the first user system indicating a degraded condition of media received by the first user system from the second user system. Responsive to receiving the indication, the method provides attempting to establish a connection with a third user system associated with the second user when the degraded condition comprises inactivity of the media being received by the first user system from the second user system. Upon establishing the connection with the third user system, the method provides connecting the third user system to the first user system to continue the communication session.

Abstract: Embodiments include devices, systems and/or methods of communicating with a vehicle (102) along a transportation route (104). For example, a system may include a plurality of access points (APs) (120) along the transportation route, an AP of the plurality of APs including a directional antenna (123) to communicate with the vehicle moving along the transportation route via a directional link (127); and at least one AP manager (132) to control handover of the vehicle between the plurality of APs. Communicating with the vehicle may include switching a directional antenna of an AP of the plurality of APs between a plurality of beam settings to steer the directional antenna towards a respective plurality of coverage areas of the transportation route. For example, AP (128) may switch directional antenna (123) between the plurality of beam settings to steer directional antenna (123) towards the respective plurality of coverage areas of transportation route (104).

Abstract: Apparatuses and methods are disclosed that may perform ranging operations between a first device and a second device. The second device transmits an FTM request frame indicating a number of supported non-legacy ACK frame formats, and receives a first FTM frame indicating capabilities of the first device to receive each of the non-legacy ACK frame formats supported by the second device. The second device selects one of the non-legacy ACK frame formats or a legacy ACK frame format based, at least in part, on the indicated capabilities of the first device, and then transmits ACK frames using the selected frame format during the ranging operation.

Abstract: Wireless communication via a mesh network of connected movable objects is described. A method includes determining, by a device including a processor, a value of a characteristic of a first movable object of movable objects communicatively coupled to a wireless network, wherein the movable objects are automated vehicles, and wherein the determining the value is based on a likelihood of receipt of a message transmitted from the first movable object to a second movable object of the movable objects. The method also includes generating information usable to move the first movable object in a manner that satisfies a defined condition associated with the value. The information can be strength of a wireless communication channel between the first movable object and a second movable object of the movable objects.

Abstract: A method for controlling a plurality of network interfaces of an electronic device includes: providing at least one table comprising information associated with a plurality of routing costs, wherein the routing costs correspond to at least paths between each of the network interfaces of the electronic device and the other electronic devices; and referring to the at least one table to select a specific network interface to transmit/receive data, and to disable at least one of the unused network interfaces.

Abstract: Disclosed are various embodiments for a call routing application. Routes are evaluated according to selection scores of call routes. The selection scores are calculated based on weighted call quality data corresponding to past calls on the call routes. A call route is selected according to an evaluation including call costs or other criteria. A call is then routed via the selected call route to the call endpoint.

Abstract: A wireless communication device has: wireless communication unit; calculation unit for calculating an evaluation value based on an opportunity for communication with the access providing device; transmission unit for transmitting the evaluation value to the other wireless communication device; acquisition unit for acquiring an evaluation value for the other wireless communication device; and communication control unit. When the other wireless communication device has more opportunities for communication than the wireless communication device does, the communication control unit preferably transmits uplink information, but when the other wireless communication device has less opportunity for communication than the wireless communication device does, the communication control unit preferably transmits downlink information.

Abstract: The present invention relates to a mobile terminal and a method for controlling the same, the mobile terminal including a location information module configured to acquire location information related to the mobile terminal based on one of a first positioning method that is configured to detect access points (APs) adjacent to the mobile terminal, receive location information related to the detected APs, and acquire the location information on the mobile terminal based on the received location information related to the APs, and a second positioning method that is configured to receive location information related to the detected APs and other APs located within a predetermined area where the detected APs are located, and acquire the location information on the mobile terminal based on the received location information related to the APs, a communication unit configured to perform wireless communication with a first positioning server providing first AP information including the location information related to

Abstract: A method and apparatus for performing autonomous denial for dual connectivity in a wireless communication system is provided. A user equipment (UE) receives an autonomous denial rate from a network, and applies the received autonomous denial rate to at least one of a master cell group (MCG) or a secondary cell group (SCG). The UE is connected to both a master evolved NodeB (MeNB), associated with the MCG, and a secondary eNB (SeNB), associated with the SCG, in dual connectivity.

Abstract: A system and method for vehicle safety that automatically controls a communication device provided with a motion detection system which provides the motion of the vehicle to a micro-processing unit embedded in a communication device that disables certain functions of the communication device depending on the speed of the vehicle. The inventive system includes a sensor to detect vehicle motion and a set of instructions stored inside a non-volatile storage media coupled to processor. When a motion is detected, the system gets initiated and alters the functionality of the communication device depending upon the speed of the vehicle.

Abstract: Systems, methods, or apparatus may comprise a computing device to transmit a first plurality of beacon frames, where each beacon frame includes a first network identifier, and a second plurality of beacon frames, where each beacon frame includes a different second network identifier. Further, the computing device may also cause the wireless transceiver to transmit the first plurality of beacon frames using a transmission parameter, and transmit the second plurality of beacon frames using a different transmission parameter—that differs from the transmission parameter of the first plurality of beacon frames.

Abstract: A wireless access setting device is disclosed. The wireless access setting device includes a wireless access point and a wireless access controller connected thereof. The wireless access point broadcasts target identification data, and the wireless access controller presets pairing data for the target identification data corresponding to virtual local area networks (VLANs). When a wireless communication device receives the target identification data, the wireless communication device transmits its first media access control address to the wireless access point according to the target identification data to store them. The wireless access point transmits its second media access control address, the first media access control address and the target identification data corresponded thereof to the wireless access controller to store them, there by cooperating with the pairing data to control the wireless communication device and the corresponding VLAN to transmit packets through the wireless access point.

Abstract: Described herein are methods and devices in which agreements between a wireless station and an access point are transferred from one access point to another during a basic service set transition within an extended service set. The described techniques define methods for reducing the frame exchanges needed after association to negotiate certain parameters such as block acknowledgement agreements.

Abstract: A method for Bluetooth low energy (BLE) advertising channel assessment by a wireless communication device is described. The method includes detecting interference on one or more of a plurality of BLE advertising channels. The method also includes determining a BLE scan order in which the BLE advertising channels are selected for scanning based on the detected interference. The method further includes scanning the BLE advertising channels according to the determined BLE scan order.

Abstract: A method for a user equipment (UE) performing measurements is provided. The UE performs measurements for a first cell and measurements for a second cell. If the first cell corresponds to a primary cell, a first measurement subframe pattern is applied to perform the measurement for the first cell. If the second cell does not correspond to the primary cell and if the second cell is in a deactivated state, a measurement timing configuration for a discovery signal is applied to perform the measurement for the second cell.