The technologies described herein are generally directed to, in response to feature activation at an access point, planning and deploying service elements of a network service across transport and core network segments in a fifth generation (5G) network or other next generation networks. For example, a method described herein can include receiving a request to implement a network service in a network that includes access point equipment connected via a transport segment to a core network segment. The method can further include, based on the request, selecting deployment locations in the network for service elements to enable the network service, with an element of the service elements being selected to be deployed at a deployment location. Further, the method can include deploying the service element at the selected deployment location.

The technologies described herein are generally directed to, in response to feature activation at an access point, planning and deploying service elements of a network service across transport and core network segments in a fifth generation (5G) network or other next generation networks. For example, a method described herein can include receiving a request to implement a network service in a network that includes access point equipment connected via a transport segment to a core network segment. The method can further include, based on the request, selecting deployment locations in the network for service elements to enable the network service, with an element of the service elements being selected to be deployed at a deployment location. Further, the method can include deploying the service element at the selected deployment location.

Intelligent, automated, fixed wireless internet planning (e.g., using a computerized tool) is enabled. For instance, a system can comprise a processor and a memory that stores executable instructions that, when executed by the processor, facilitate performance of operations, comprising: determining, for a user equipment determined to be within a defined coverage area, a signal to interference and noise ratio, based on the signal to interference and noise ratio, determining a spectral efficiency value corresponding to the user equipment, based on the spectral efficiency value and a total available bandwidth of a network via which the defined coverage area is enabled, determining an available throughput corresponding to the user equipment, and in response to a determination that the available throughput exceeds a threshold throughput, designating the user equipment, in a data store, as being covered within the defined coverage area by the total available bandwidth of the network.

Intelligent, automated, fixed wireless internet planning (e.g., using a computerized tool) is enabled. For instance, a system can comprise a processor and a memory that stores executable instructions that, when executed by the processor, facilitate performance of operations, comprising: determining, for a user equipment determined to be within a defined coverage area, a signal to interference and noise ratio, based on the signal to interference and noise ratio, determining a spectral efficiency value corresponding to the user equipment, based on the spectral efficiency value and a total available bandwidth of a network via which the defined coverage area is enabled, determining an available throughput corresponding to the user equipment, and in response to a determination that the available throughput exceeds a threshold throughput, designating the user equipment, in a data store, as being covered within the defined coverage area by the total available bandwidth of the network.

The subject matter described herein provides systems and techniques for a network planning and optimization tool that may allow for network capacity planning using key network failures for an arbitrary pair of network topology and demands. Performing network capacity planning with key network failures, instead of using other techniques, may avoid over-building the topology of a network. In particular, key network failures may be generated from the probabilistic failures, and the impact of these failures on a network may be computed. Expected flow availability SLO or a function thereof may be computed, using this information, and used by the tool to design a robust network. With an embedded flow availability calculation and updated risk framework, the capacitated cross-layer network topologies output by the tool may meet network demands/flows with their respective SLO type at the lowest cost.

A construction system for recurrent Bayesian networks, a construction method for recurrent Bayesian networks, a computer-readable recording medium, a non-transitory computer program product, and a radio network control system are provided. The method is performed by a processor, and includes: establishing an initial population, and setting the initial population as a current population; establishing a corresponding recurrent Bayesian network for each CPPN in the current population, to obtain a set of recurrent Bayesian networks corresponding to the current population; evolving the current population by using an evolutionary algorithm and a fitness function to obtain a next population; determining whether a termination condition is met; and repeatedly performing the foregoing steps in response to the termination condition being not met, and selecting a solution network in the current population as the task network based on the fitness function in response to the termination condition being met.

A construction system for recurrent Bayesian networks, a construction method for recurrent Bayesian networks, a computer-readable recording medium, a non-transitory computer program product, and a radio network control system are provided. The method is performed by a processor, and includes: establishing an initial population, and setting the initial population as a current population; establishing a corresponding recurrent Bayesian network for each CPPN in the current population, to obtain a set of recurrent Bayesian networks corresponding to the current population; evolving the current population by using an evolutionary algorithm and a fitness function to obtain a next population; determining whether a termination condition is met; and repeatedly performing the foregoing steps in response to the termination condition being not met, and selecting a solution network in the current population as the task network based on the fitness function in response to the termination condition being met.

A user equipment according to one aspect is a user equipment of a cellular communication system, the user equipment comprising a communicator configured to perform a radio communication by WLAN and/or Bluetooth, a cellular receiver configured to receive a configuration message which is transmitted from a network of the cellular communication system and sets an MDT measurement in which the cellular communication system is set as a measurement target, a controller configured to perform a radio measurement on the cellular communication system based on the configuration message, and a cellular transmitter configured to transmit, to the network, MDT measurement information including a measurement result for the cellular communication system. The controller is configured to include the measurement result for the WLAN and/or the Bluetooth in the MDT measurement information when the measurement result for the WLAN and/or the Bluetooth is available.

A user equipment according to one aspect is a user equipment of a cellular communication system, the user equipment comprising a communicator configured to perform a radio communication by WLAN and/or Bluetooth, a cellular receiver configured to receive a configuration message which is transmitted from a network of the cellular communication system and sets an MDT measurement in which the cellular communication system is set as a measurement target, a controller configured to perform a radio measurement on the cellular communication system based on the configuration message, and a cellular transmitter configured to transmit, to the network, MDT measurement information including a measurement result for the cellular communication system. The controller is configured to include the measurement result for the WLAN and/or the Bluetooth in the MDT measurement information when the measurement result for the WLAN and/or the Bluetooth is available.

The disclosure relates to a 5G or 6G communication system for supporting a higher data transmission rate. The disclosure provides a method and apparatus for quickly performing cell activation in a wireless communication system. The method of UE comprises receiving, from a base station, first channel measurement configuration information and second channel measurement configuration information that include channel measurement signal information; receiving, from the base station, MAC CE for a cell activation or a cell deactivation; identifying, based on the MAC CE, at least one cell in which the cell activation is indicated for the terminal; determining, based on the first channel measurement configuration information and the second channel measurement configuration information, channel measurement configuration information for the at least one cell in which the cell activation is indicated; and performing the cell activation based on the second channel measurement configuration information and the MAC CE.