In a system where a first node provides a first area of TDD coverage on a first TDD carrier using a first TDD configuration and an adjacent second node provides a second area of TDD coverage on a second TDD carrier using a different second TDD configuration, the first node could additionally provide an area of FDD coverage on a first FDD carrier, including causing the area of FDD coverage to sit at least partially between the first and second areas of TDD coverage and therefore to define a spatial buffer between the first and second areas of TDD coverage. For instance, the first access node could restrict its service on the first TDD carrier to be for user equipment devices (UEs) that are relatively close to the first access node and could restrict its service on the first FDD carrier to be for UEs that are relatively far away from the first access node.

Systems and methods provide automated generation of neighbor frequency lists for configuration of frequency objects for wireless stations. A computing device selects a target sector carrier of a wireless station of multiple wireless stations in a radio access network and identifies, based on distances from the wireless station, neighboring sector carriers of the target sector carrier. The computing device filters the neighboring sector carriers based on an azimuth of the target sector carrier to form a filtered set of neighboring sector carriers. The computing device calculates a probability of neighboring frequencies for the target sector carrier based on locations of the filtered set of neighboring sector carriers and generates, based on the calculating, a neighbor frequency list for the target sector carrier. The neighbor frequency list is used to configure frequency objects, for the target sector carrier, that ensure seamless handovers within the radio access network.

A method of operating a communicator includes operating a first receiver of a plurality of receivers on a first channel of a series of channels. A second receiver of the plurality of receivers is operated on a second channel of the series of channels. A third receiver of the plurality of receivers is operated on a third channel of the series of channels. The second receiver that operates on the second channel includes a reception overlap period of about 25% to about 75% with the first receiver that operates on the first channel and a reception overlap period of about 25% to about 75% with the third receiver that operates on the third channel.

A method of operating a communicator includes operating a first receiver of a plurality of receivers on a first channel of a series of channels. A second receiver of the plurality of receivers is operated on a second channel of the series of channels. A third receiver of the plurality of receivers is operated on a third channel of the series of channels. The second receiver that operates on the second channel includes a reception overlap period of about 25% to about 75% with the first receiver that operates on the first channel and a reception overlap period of about 25% to about 75% with the third receiver that operates on the third channel.

A method, a device, and a non-transitory storage medium are described in which a registration area-based application exposure and network slice selection service is provided. The service may include the generation of multiple sets of allowed network slices based on a type of end device, current tracking area, and registration area information. The service may also include selecting one of the sets of allowed network slices based on a mobility pattern of the end device. The service may also translate allowed network slices, current tracking area and registration area information, and expose the translated information to an application function.

Fifth generation and beyond (5G+) systems are expected to adopt new network architectures, services, and deployment schemes for compatibility with the latest technologies and end user's needs. With increase in user equipment (UE), also come variety of advanced applications and use-cases, wherein each application type has its own KPI requirements. Existing resource allocation schemes in cellular networks are not able to handle such dynamic requirements due to which network slice can lead to unwanted mismanagement of resources. Present application provides systems and methods for application-aware dynamic slicing in radio access network (RAN), wherein RAN slicing is proactively managed by learning historical slice demands and consumptions. Once slices are created, the system allocates resources to user equipment by following optimal inter-slice and intra-slice mechanisms based on application type(s), traffic demand(s) and wireless characteristics of UE. Upon resource allocation the UE are further monitored to avoid resource misutilization and resource wastage.

Infrastructure comprising a wide area network (WAN) is adapted as a transport network portion of a 5G network in which the WAN is sliced at the optical layer on a discrete wavelength basis to provide dedicated network capacity to customers such as service providers, application providers, and network operators. Optical layer slicing extends the slicing construct for a radio access network (RAN) portion of the 5G network through to the WAN to provide end-to-end 5G network slicing from user equipment (UE) accessing an air interface of the network to application servers that are instantiated in data centers in a network cloud portion of the 5G network.

Infrastructure comprising a wide area network (WAN) is adapted as a transport network portion of a 5G network in which the WAN is sliced at the optical layer on a discrete wavelength basis to provide dedicated network capacity to customers such as service providers, application providers, and network operators. Optical layer slicing extends the slicing construct for a radio access network (RAN) portion of the 5G network through to the WAN to provide end-to-end 5G network slicing from user equipment (UE) accessing an air interface of the network to application servers that are instantiated in data centers in a network cloud portion of the 5G network.

A network provider implements network slicing. Network instances are instantiated on a communication network that are configured to provide a configured set of services that are accessible to a controlled set of devices. When a first device is either registered or authenticated with the communication network or has entered a service area, a service profile is identified and analyzed. In response to determining that the service profile matches a configured set of services for one of the instantiated network instances, the first device is enabled to access the matching instantiated network instance.

A network provider implements network slicing. Network instances are instantiated on a communication network that are configured to provide a configured set of services that are accessible to a controlled set of devices. When a first device is either registered or authenticated with the communication network or has entered a service area, a service profile is identified and analyzed. In response to determining that the service profile matches a configured set of services for one of the instantiated network instances, the first device is enabled to access the matching instantiated network instance.