A system is provided that includes one management cluster to manage network function virtualization infrastructure (NFVI) resources lifecycle in more than one edge POD locations, where resources include hardware and/or software, and where software resources lifecycle includes software development, upgrades, downgrades, logging, monitoring etc. Methods are provided for decoupling storage from compute and network functions in each virtual machine (VM)-based NFVI deployment location and moving it to a centralized location. Centralized storage could simultaneously interact with more than one edge PODs, and the security is built-in with periodic key rotation. Methods are provided for increasing NFVI system viability by dedicating (fencing) CPU core pairs for specific controller operations and workload operations, and sharing the CPU cores for specific tasks.

Embodiments of the present disclosure provide a resource reporting method, a terminal device, and a network device. The terminal device may select a resource to listen to and select a resource to report. In addition, the resource listening approach and the resource reporting approach can be flexibly determined. Therefore, the communication requirements of Release 15 or higher releases can be satisfied. The method includes a terminal device reports to a network device the measurement result of a first wireless time-frequency resource used for terminal-to-terminal communication. The terminal device is a terminal device supporting a network scheduling mode of a terminal-to-terminal communication resource.

According to the remote operation system or a remote operation server 20 included in the remote operation system, when the “environment information control process” is performed, a data amount of environment data is reduced such that the reduction in the information amount of one or a plurality of low environment information factors is greater than the reduction in the information amount of one or a plurality of high environment information factors (meaning the reduction in the information amount of the environment information due to a change in the environment information factor). The environment information control process is performed by classifying the environment information factors into the high environment information factor and the low environment information factor according to a difference in the operation state.

The present disclosure can provide a method, device, terminal and system for transmitting data. The method for transmitting data includes: receiving target data from a target gateway via a channel to be detected; detecting whether an interference signal from another terminal for data transmission with the target gateway exists on the channel to be detected within the preset frame interval duration; and stopping receiving the target data when the interference signal exists until the channel to be detected is determined to be idle, and continuing to receive the target data via the idle channel to be detected.

Techniques for providing visualization and analysis of performance data are disclosed. In one particular exemplary embodiment, the techniques may be realized as a system for providing visualization and analysis of performance data. The system may comprise one or more processors communicatively coupled to a mobile communications network. The one or more processors may be configured to provide a user interface at a mobile device for a user to view network performance data associated with the mobile communications network. The one or more processors may further be configured provide one or more user-selectable options to a user at a mobile device to view the network performance data. The one or more processors may also be configured to dynamically filter the network performance data based on the one or more user-selectable options. The one or more processors may further be configured to provide a visualization to be displayed at the mobile device based on the dynamically filtered network performance data, where the visualization presents one or more views that identity potential problems associated with the mobile communications network to allow the user to improve customer experience assurance.

Aspects of the subject disclosure may include, for example, selecting a first pathway of available pathways during a first time period according to predicted opportunities for a mobile communication device to access a first network via the available pathways, and directing transmission of first data to the mobile communication device via the first pathway during the first time period, wherein a presence of a second data at the mobile communication device enables an application to access the first data at the mobile communication device. Other embodiments are disclosed.

Aspects of the subject disclosure may include, for example, selecting a first pathway of available pathways during a first time period according to predicted opportunities for a mobile communication device to access a first network via the available pathways, and directing transmission of first data to the mobile communication device via the first pathway during the first time period, wherein a presence of a second data at the mobile communication device enables an application to access the first data at the mobile communication device. Other embodiments are disclosed.

Embodiments of the present disclosure may relate to mechanism for tuning to an available channel in a narrow band wireless network. In an embodiment, a base station [104] may transmit a channel list (comprising available channel/s) to a NB-IoT device [102] that may transmit a channel request (comprising operational mode of the NB-IoT device [102]) back to the base station [104]. The base station [102] may define a first parameter and a second parameter based on said operational mode and accordingly determine an allocation scheme. Subsequently, the base station [104] may transmit the allocation scheme indicative of the allocation of the available channels to the NB-IoT device [102] such that the NB-IoT device [102] tunes to the available channel/s. In another embodiment, the NB-IoT device [102] may itself tune to the available channel/s and may transmit a notification message to each of the available channel/s based on said tuning.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) configured as a drone-coupled wireless device may be configured to transmit a message indicating information relating to the drone-coupled wireless device (e.g., aerial state, non-aerial state, airborne status, drone capability, quality of service (QoS) requirements of a drone service) to a base station. The message may also carry a session connectivity request, which the base station may use to determine that the UE is a drone-coupled wireless device, establish a bearer appropriate for a subscription service of the UE (e.g., as indicated by the drone capability), and apply appropriate protocols for the UE.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) configured as a drone-coupled wireless device may be configured to transmit a message indicating information relating to the drone-coupled wireless device (e.g., aerial state, non-aerial state, airborne status, drone capability, quality of service (QoS) requirements of a drone service) to a base station. The message may also carry a session connectivity request, which the base station may use to determine that the UE is a drone-coupled wireless device, establish a bearer appropriate for a subscription service of the UE (e.g., as indicated by the drone capability), and apply appropriate protocols for the UE.