In a wireless communication system including a plurality of base stations to which terminal stations are connectable and a base station control device which controls each of the base stations, the base station control device includes an information collection unit configured to collect wireless environment information indicating wireless environments around the base stations and the terminal stations from each of the base stations, a parameter calculation unit configured to calculate a parameter for correcting radio wave interference relationship among the base stations based on the wireless environment information collected by the information collection unit and priority set in advance for each of the base stations, and a transmission unit configured to transmit the parameter calculated by the parameter calculation unit to each of the base stations, and each of the base stations includes a reception unit configured to receive the parameter transmitted by the transmission unit, and a setting unit configured to perform setting so as to correct radio wave interference relationship with other base stations based on the parameter received by the reception unit.

In a wireless communication system including an intermediate processing device which performs processing between a plurality of base stations to which terminal stations are connectable and a base station control device which controls each of the base stations, the intermediate processing device includes an information collection unit configured to collect wireless environment information which includes information regarding the terminal stations connected to the base stations and which indicates wireless environments around the base stations and the terminal stations, from each of the base stations, a first conversion unit configured to convert the wireless environment information collected by the information collection unit into first information which is equally processable by the base station control device without distinction for each of the base stations, a transmission unit configured to transmit the first information to the base station control device, a reception unit configured to receive a parameter calculated by the base station control device based on the first information, and a second conversion unit configured to convert the parameter received by the reception unit into individual second information in accordance with each of the base stations, and each of the base stations includes a reception unit configured to receive the second information and a setting unit configured to perform setting so as to perform communication with each of the terminal stations based on the second information.

In a wireless communication system including an intermediate processing device which performs processing between a plurality of base stations to which terminal stations are connectable and a base station control device which controls each of the base stations, the intermediate processing device includes an information collection unit configured to collect wireless environment information which includes information regarding the terminal stations connected to the base stations and which indicates wireless environments around the base stations and the terminal stations, from each of the base stations, a first conversion unit configured to convert the wireless environment information collected by the information collection unit into first information which is equally processable by the base station control device without distinction for each of the base stations, a transmission unit configured to transmit the first information to the base station control device, a reception unit configured to receive a parameter calculated by the base station control device based on the first information, and a second conversion unit configured to convert the parameter received by the reception unit into individual second information in accordance with each of the base stations, and each of the base stations includes a reception unit configured to receive the second information and a setting unit configured to perform setting so as to perform communication with each of the terminal stations based on the second information.

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.

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.

A real-time spectrum optimization and allocation is provided within multifunction, co-located, interacting heterogeneous networks. Quantum statistical allocation techniques may be adapted to networks with nodes that behave indistinguishably and distinguishably, within a common geographic locational area. If the network nodes are indistinguishable, their statistical behavior may be Fermionic or Bosonic. Fermionic nodes occupy a single or the same state with some form of degeneracy. Bosonic nodes may occupy a single or the same state, with or without degeneracy. If the nodes are distinguishable, then their statistical behavior is Boltzmann-like, and they may occupy the same state provided there is degeneracy to the overall bandwidth allowing information to be transferred.

A real-time spectrum optimization and allocation is provided within multifunction, co-located, interacting heterogeneous networks. Quantum statistical allocation techniques may be adapted to networks with nodes that behave indistinguishably and distinguishably, within a common geographic locational area. If the network nodes are indistinguishable, their statistical behavior may be Fermionic or Bosonic. Fermionic nodes occupy a single or the same state with some form of degeneracy. Bosonic nodes may occupy a single or the same state, with or without degeneracy. If the nodes are distinguishable, then their statistical behavior is Boltzmann-like, and they may occupy the same state provided there is degeneracy to the overall bandwidth allowing information to be transferred.

The disclosure relates to an electronic device for wireless communication, a wireless communication method and a computer readable medium. According to an embodiment, an electronic device for wireless communication includes a processing circuitry. The processing circuitry is configured to acquire a parameter related to a behavior characteristic of a mobile access point. The processing circuitry is further configure to determine a spectrum allocation manner for the mobile access point based on the parameter.

The disclosure relates to an electronic device for wireless communication, a wireless communication method and a computer readable medium. According to an embodiment, an electronic device for wireless communication includes a processing circuitry. The processing circuitry is configured to acquire a parameter related to a behavior characteristic of a mobile access point. The processing circuitry is further configure to determine a spectrum allocation manner for the mobile access point based on the parameter.

A wireless device receives configuration parameters of a first bandwidth part (BWP) and a second BWP of an unlicensed cell. A first contention window is determined for a first listen before talk (LBT) procedure for a first channel of the first BWP. Based on switching from the first BWP to the second BWP, a second contention window is determined to be a minimum contention window, of a plurality of contention windows, for a second LBT procedure of a second channel of the second BWP. A transport block is transmitted, via the second BWP, based on the second LBT procedure using the second contention window.