Abstract: This disclosure describes systems, methods, and devices related to delay indication. A device may identify a first frame received from a first station device, wherein the first frame comprises a first transition delay field, wherein the first transition delay field comprises a first transition delay value associated with a power state transition. The device may determine a wake up receiver (WUR) frame comprising an indication for waking up the main radio of the first station device. The device may cause to send the WUR frame to the first station device based on the first transition delay value.

Abstract: A mobile application for facilitating configuration and installation of networking and extender devices in a local area network utilizes augmented reality to provide configuration guidance information and network information. For configuring the networking device, a camera of the mobile computing device captures an image depicting the networking device, which is displayed on a touchscreen display of the mobile computing device with graphical elements including icons and textual information overlaid on the image to indicate configuration guidance information. Similarly, for installing the extender device, the camera captures image data depicting areas of the premises where the device is being installed and graphical elements are overlaid on the image data indicating network information such as the position of a previously installed networking device as well as the signal strength of wireless signals from the networking device.

Abstract: A method and a device for transmitting a wake-up frame in a wireless LAN system are proposed. In particular, the transmission device configures a PPDU to which a first wireless LAN system is applied. The transmission device transmits, via the PPDU, a wake-up frame to which a second wireless LAN system is applied. The PPDU is transmitted via a first frequency band. The PPDU comprises a signal field and a data field. The signal field indicates that a data frame is transmitted in at least one RU excluding three 26-RUs located at the center of a second frequency band included in the first frequency band. The wake-up frame is transmitted via a 4 MHz band located at the center of the three 26-RUs. A coefficient is inserted in a first subcarrier constituting the 4 MHz band. The wake-up frame has an OOK scheme applied thereto and thus comprises an on signal and an off signal.

Abstract: There is provided for supporting beam correspondence. The method may be performed by a user equipment (UE) and comprise: transmitting UE capability information to a base station. The UE capability information may include first information related a capability of supporting beam correspondence. The beam correspondence may be determined based on at least a beam correspondence tolerance requirement. The beam correspondence tolerance requirement may include a delta effective isotropic radiated power (EIRP) of 3 dB.

Abstract: Example embodiments presented herein are directed towards a wireless terminal and base station, and corresponding methods therein, for providing a handover for a subset of bearers associated with the wireless terminal. The subset of bearers is less than a total number of bearers associated with the wireless terminal. Thus, upon the completion of the handover procedure, at least one bearer will stay connected with a source base station.

Abstract: The present invention relates to a wireless communication system and a method and a device for transmitting uplink data packet based on QoS framework in wireless communication system, the method comprising: receiving uplink (UL) packet with a first QoS flow ID from an upper layer; checking whether the first QoS flow ID is prohibited or not based on QoS flow prohibition information; and determining whether to transmit the UL packet according to result of checking; wherein the UL packet of the first QoS flow ID is not transmitted if the first QoS flow ID is prohibited; and wherein the UL packet with the first QoS flow ID is transmitted to a network via a DRB, if the first QoS flow is not prohibited. The UE is capable of communicating with at least one of another UE, a UE related to an autonomous driving vehicle, a base station or a network.

Abstract: Provided is an apparatus and method for encoding/decoding a moving picture based on adaptive scanning. The moving picture apparatus and method can increase a compression rate based on adaptive scanning by performing intra prediction onto blocks of a predetermined size, and scanning coefficients acquired from Discrete Cosine Transform (DCT) of a residue signal and quantization differently according to the intra prediction mode. The moving picture encoding apparatus includes: a mode selector for selecting and outputting a prediction mode; a predictor for predicting pixel values of pixels to be encoded of an input video based on the prediction mode to thereby output a residue signal block; a transform/quantization unit for performing DCT onto the residue signal block and quantizing the transformed residue signal block; and an encoder for adaptively scanning and encoding the quantized residue signal block based on the prediction mode.

Abstract: In one embodiment, a technique comprises monitoring data transfer over a radio frequency (RF) link between a first device and a second device in a mesh network where the second device is a descendent node and the first device is a parent node. The technique further transfers the data over a power link communication (PLC) when the RF link is inactive. The method also includes broadcasting, by the second device, RF link availability to at least a third device in the mesh network when the RF link with the first device is inactive where the third device has an active link with the second device and the third device is a descendent node of the second device. The method then includes communicating, between the second device and the third device, through the active RF link.

Abstract: A method for switching data between virtual machines is provided, the method includes acquiring data that is inside a physical host and needs to be sent to a destination node; determining, according to the data, whether the destination node is a node inside the physical host or a node outside the physical host; and when the destination node is a node inside the physical host, determining a destination virtual network interface card (NIC) port, and sending the data to a corresponding destination virtual machine using a virtual NIC corresponding to the destination virtual NIC port; or when the destination node is a node outside the physical host, determining a physical NIC port, and sending the data outside the physical host using a physical NIC corresponding to the physical NIC port. A corresponding apparatus and system are also provided.

Abstract: A method and apparatus for supporting a device-to-device (D2D) communication between user equipments (UEs) are provided. A method of transmitting device-to-device (D2D) data using a D2D data transmission resource by a user equipment (UE), the method including: receiving, at a UE, configuration information associated with a D2D data transmission resource, the configuration information including information of a D2D data allocation period and being transmitted from an evolved NodeB (eNB); determining, at the UE, a D2D data transmission resource in each D2D data allocation period, the D2D data transmission resource including a pool of subframes; selecting D2D data transmission subframes from among the pool of subframes based on a changed pattern, the changed pattern being derived from a basic pattern; and transmitting, from the UE to another UE, D2D data based on the selected D2D data transmission subframes.

Abstract: Provided is a method and a device for transmitting an Ack/Nack of sPUCCH in response to the reception of short TTI-based sPDSCH in a 3GPP LTE/LTE-Advanced system. A base station may set, for each terminal, an offset value for setting a link between sPDSCH and sPUCCH, and transmit the set offset value to the terminal through upper layer signaling (RRC signaling), thereby enabling a terminal to use the offset value to allocate sPUCCH resources for transmitting an Ack/Nack in response to the reception of sPDSCH.

Abstract: Intelligent delivery/transmission of data within a secure transmission path of a distributed computing network. A plurality of logical switches are disposed throughout a secure transmission path between a source and target. A controller is configured to control a timing for delivery and/or routing of the data packets to the target apparatus by activating and deactivating the logical switches. In addition, activation of two or more switches provides for isolating data, such that, inline processing (e.g., security checks or the like) can be performed on the data.

Abstract: Methods and systems for managing data transmissions are disclosed. An example method can comprise determining a plurality of time allocations for a time cycle. The plurality of time allocations can comprise a first time allocation which can be determined based on an information rate, a committed information rate, an excess information rate, an effective bandwidth rate, other factors, or a combination thereof. Data can be received from multiple sources into a buffer, for example, and can be processed within a time cycle if processing the data will not exceed the time allocation.

Abstract: The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. According to the embodiment of the disclosure, a method of a terminal in a wireless communication system and an apparatus therefor are provided.

Abstract: A method and a router device for managing memory for network overlay routes with fallback route support prioritization may be provided. A network overlay route as a candidate network overlay route may be obtained at a router for storage in a memory. The memory may store a plurality of network overlay routes for forwarding user plane traffic in a network. An assessment for storage of the candidate network overlay route based on a priority level indicator of the candidate network overlay route may be performed. The priority level indicator may be indicative of a fallback route support level of the candidate network overlay route in the router. Based on the assessment, at least one of the following may be performed: adding the candidate network overlay route to the memory and refraining from adding the candidate network overlay route to the memory.

Abstract: Described embodiments provide systems and methods for securing communications between services in a cluster using load balancing. A first proxy of a first node of a cluster of nodes can receive a request for a service from at least one pod of the first node. The service can include a plurality of pods. The plurality of pods can execute in the cluster of nodes including the first node. The first proxy can select, responsive to a load balancing determination, a pod of a second node of the cluster of nodes to receive the request. An encrypted connection can be established with a second proxy of the second node. The request can be forwarded to the selected pod via the encrypted connection to the second proxy. The request can be decrypted at the second proxy and forwarded at the pod of the second node.

Abstract: The embodiments herein relate to timing advance offset for uplink/downlink switching in New Radio (NR). In one embodiment, there proposes a method in a wireless communication device, comprising: determining a timing advance (TA) offset for uplink/downlink switching, wherein the TA offset is at least based on the time offset requirement for uplink/downlink switching in different scenarios used in communication between the wireless communication device and a network node; applying the determined TA offset in the uplink communication from the wireless communication device to the network node. With embodiments herein, uplink/downlink switching time for NR is defined.

Abstract: Certain aspects of the present disclosure relate to methods and apparatus for collision handling in NR. In certain aspect, a method for use by a wireless communications device includes detecting a collision between resources allocated to different channels and initiating collision handling when processing the different channels based on the detection, wherein at least one of the detection or the processing is based on one or more characteristics of the different channels or the wireless device. In certain aspects, the one or more characteristics comprise at least one of one or more numerologies associated with at least one of the different channels, a modulation order of at least one of the different channels, coding rate of at least one of the different channels, or one or more capabilities of the wireless device.

Abstract: A system for network load balancing includes multiple access points (AP), multiple entertainment devices and a DHCP server. Each AP is connected to one entertainment devices and the DHCP server, each entertainment device includes a DNS server and a web server, and all DNS servers store and parse the same domain names. When the AP receives an access request of a wireless terminal, the DHCP server designates a DNS server in an entertainment device connected to the AP as a DNS server for the wireless terminal. When the AP receives a domain name parsing request of the wireless terminal, the designated DNS server parses the domain name into an IP address of a web server in the entertainment device including the DNS server. When the AP receives a web access request of the wireless terminal, the designated web server responds to the web access request via the AP.

Abstract: A method for transmitting feedback information by a remote user equipment (remote UE) in a further enhancement D2D (FeD2D) environment comprises a step of transmitting feedback information on a plurality of relay user equipments (relay UEs) which have been linked to the remote UE through a PC5 interface, wherein the feedback information is transmitted via a separate feedback channel set by a network rather than the PC5 interface, and the feedback information may be transmitted to the plurality of relay UEs in a multicast form.