The present disclosure relates to a port configuration method and device, the method comprises: receiving antenna port configuration parameters, the antenna port configuration parameters being adapted to information on transmission capability of a terminal; and determining an association relationship set between port selection parameters and demodulation reference signal DMRS port identifiers according to the antenna port configuration parameters. The present disclosure determines the association relationship set adapted to the transmission capability of the terminal by using the antenna port configuration parameters sent by a base station, and obtains the DMRS port in accordance with the determined antenna port data so as to configure the port, thereby avoiding blind configuration on the port of the terminal, improving efficiency of the terminal configuration, and reducing signaling overhead of the configuration.

Certain aspects of the present disclosure provide techniques and apparatus for determining neural network functions (NNFs) and configuring and using corresponding machine learning (ML) models for performing one or more ML-based wireless communications management procedures. An example method performed by a user equipment includes transmitting, to a base station (BS), UE capability information indicating at least one radio capability of the UE and at least one machine learning (ML) capability of the UE and receiving, from the BS based on the UE capability information, ML configuration information indicating at least one neural network function (NNF) and at least one ML model corresponding to the at least one NNF.

Methods, systems, and devices for wireless communications are described. A device may receive an indication of a subcarrier spacing (SCS) for communications in a plurality of transmission time intervals (TTIs), where a TTI include a set of symbols, a corresponding set of cyclic prefixes, and a padding duration. The device may receive a control signal indicating a configuration for the padding duration, at least a portion of which may be reallocated as one or more additional symbols with corresponding one or more additional cyclic prefixes. In some examples, the one or more additional cyclic prefixes and at least a first portion of the set of cyclic prefixes may be reduced in duration in comparison with a remaining portion of the set of cyclic prefixes. The device may communicate during the padding duration using the one or more additional symbols and the corresponding one or more additional cyclic prefixes.

A method, system, and computer program product for open flow connection between differing software-defined network controllers are provided. The method generates a networking interface between a first networking controller and a second networking controller. Networking information is exchanged between the first networking controller and the second networking controller using the networking interface. A logical switch is generated between the first networking controller and the second networking controller by matching at least a portion of the networking information of the second networking controller at the first networking controller. The method exchanges the matched portion of the networking information from the first networking controller with the second networking controller to create layer two open flow connection between the first networking controller and the second networking controller.

A network element is herein disclosed. The network element comprises a controller card and a pluggable card. The controller card comprises a first processor; a first memory, the first memory being a first non-transitory computer-readable medium storing computer-executable instructions comprising a common software stack and a first microservice stack; and a first device; wherein the first microservice stack includes a first microservice operable to manage the first device. The pluggable card comprises a second processor; a second memory, the second memory being a second non-transitory computer-readable medium storing computer-executable instructions comprising the common software stack and a second microservice stack; and a second device; wherein the second microservice stack includes a second microservice operable to manage the second device.

A network element is herein disclosed. The network element comprises a controller card and a pluggable card. The controller card comprises a first processor; a first memory, the first memory being a first non-transitory computer-readable medium storing computer-executable instructions comprising a common software stack and a first microservice stack; and a first device; wherein the first microservice stack includes a first microservice operable to manage the first device. The pluggable card comprises a second processor; a second memory, the second memory being a second non-transitory computer-readable medium storing computer-executable instructions comprising the common software stack and a second microservice stack; and a second device; wherein the second microservice stack includes a second microservice operable to manage the second device.

Disclosed is a method for automatically configuring a network address of network interfaces of communicating elements intended to form part of a home-automation system for a building and belonging to an unconfigured network part, the unconfigured network part including a head network equipment item and at least one communicating element, the network address of each network interface including a network prefix. The method is implemented subsequent to the connection of the head network equipment item to a configured communication network arranged in the form of a hierarchical network including at least two successive hierarchy levels, the method including steps of: negotiating the network prefix of the network interface of the head network equipment item; propagating the network prefix to the communicating elements belonging to the network part with a view to the automatic configuration of the network addresses of the set of network interfaces of the communicating elements.

Disclosed is a method for automatically configuring a network address of network interfaces of communicating elements intended to form part of a home-automation system for a building and belonging to an unconfigured network part, the unconfigured network part including a head network equipment item and at least one communicating element, the network address of each network interface including a network prefix. The method is implemented subsequent to the connection of the head network equipment item to a configured communication network arranged in the form of a hierarchical network including at least two successive hierarchy levels, the method including steps of: negotiating the network prefix of the network interface of the head network equipment item; propagating the network prefix to the communicating elements belonging to the network part with a view to the automatic configuration of the network addresses of the set of network interfaces of the communicating elements.

An eNB and a method for use in a base station (eNB) for configuring a UE to be awake for a longer duration in order to detect eNB transmission after the end of initial Signalling.

An eNB and a method for use in a base station (eNB) for configuring a UE to be awake for a longer duration in order to detect eNB transmission after the end of initial Signalling.