An electronic device is provided. The electronic device includes a communication circuit including at least one antenna, a memory, and a processor operatively connected with the communication circuit and the memory. The memory includes instructions, when executed, causing the processor to identify a communication state of the communication circuit, adjust a characteristic of the antenna to a wideband characteristic including a first wireless-fidelity (Wi-Fi) band and a second Wi-Fi band by means of the communication circuit to scan a Wi-Fi communication channel, when the identified communication state is a state where the Wi-Fi communication channel is scanned, and adjust the characteristic of the antenna to a narrowband characteristic corresponding to a determined communication channel to perform Wi-Fi communication, when the identified communication state is a state where the Wi-Fi communication channel to communicate is determined.

A method, a system, and a non-transitory storage medium are described which provide for generating, by a wireless station of a multi-radio access technology (RAT) radio access network (RAN) that includes a new radio (NR) RAN and a RAN of a Long Term Evolution (LTE) network, a non-system information block (SIB) message that includes cell reselection priority information and NR stand-alone (SA) neighboring cell information, wherein an order of priority configures an end device attached to the LTE RAN to reselect to a first radio frequency (RF) channel of a first NR SA neighboring cell; and broadcasting the non-SIB message to the end device.

A method, a system, and a non-transitory storage medium are described which provide for generating, by a wireless station of a multi-radio access technology (RAT) radio access network (RAN) that includes a new radio (NR) RAN and a RAN of a Long Term Evolution (LTE) network, a non-system information block (SIB) message that includes cell reselection priority information and NR stand-alone (SA) neighboring cell information, wherein an order of priority configures an end device attached to the LTE RAN to reselect to a first radio frequency (RF) channel of a first NR SA neighboring cell; and broadcasting the non-SIB message to the end device.

Aspects described herein relate to concurrently communicating with a base station over multiple frequency bands using a same first beam, and switching, according to beam switching criteria, from the first beam to a second beam during a time period, wherein the time period is based on a timing reference associated with a reference band.

Aspects described herein relate to concurrently communicating with a base station over multiple frequency bands using a same first beam, and switching, according to beam switching criteria, from the first beam to a second beam during a time period, wherein the time period is based on a timing reference associated with a reference band.

A method for identifying a problem cell, an electronic device and a computer-readable medium Said method comprises: determining the anomaly contribution degree of each cell in a subnet(S101); and determining at least one cell as a problem cell according to the anomaly contribution degree of each cell in the subnet (S102); the anomaly contribution degree of each cell refers to, when the key performance indicator of the subnet is anomalous, the degree of correlation between the key performance indicator of the cell and the anomaly; the key performance indicator of the subnet being anomalous means that the key performance indicator of the subnet exceeds a first threshold range; the key performance indicator of the subnet is determined according to parameter statistics of cells therein; and the key performance indicator of the cell is determined according to parameter statistics therein. Disclosed are a method for identifying a problem cell, an electronic device, and a non-transitory computer-readable medium. The method includes: determining an anomaly contribution degree of each cell in a subnet; and determining at least one cell as a problem cell according to the anomaly contribution degree of each cell in the subnet.

A method for identifying a problem cell, an electronic device and a computer-readable medium Said method comprises: determining the anomaly contribution degree of each cell in a subnet(S101); and determining at least one cell as a problem cell according to the anomaly contribution degree of each cell in the subnet (S102); the anomaly contribution degree of each cell refers to, when the key performance indicator of the subnet is anomalous, the degree of correlation between the key performance indicator of the cell and the anomaly; the key performance indicator of the subnet being anomalous means that the key performance indicator of the subnet exceeds a first threshold range; the key performance indicator of the subnet is determined according to parameter statistics of cells therein; and the key performance indicator of the cell is determined according to parameter statistics therein. Disclosed are a method for identifying a problem cell, an electronic device, and a non-transitory computer-readable medium. The method includes: determining an anomaly contribution degree of each cell in a subnet; and determining at least one cell as a problem cell according to the anomaly contribution degree of each cell in the subnet.

Method and apparatus for switching BWP based on UE feedback. The apparatus identifies a potential change of resources of a carrier based on an event or a condition associated with communication with a base station. The apparatus provides, to the base station, a preferred throughput or BWP as the potential change of resources for the carrier. The apparatus switches to the preferred throughput or BWP for the carrier. The apparatus receives, from the base station, a switch indication including instructions to switch to the preferred throughput or BWP for the carrier. The apparatus selects a preferred throughput or BWP as the potential change of resources.

An unmanned aerial vehicle (UAV) has a first radio configured to operate on one of a plurality of radio frequency (RF) channels, a processing and management application program interface (API), and a controller. A system for active radio frequency (RF) channel switching includes the UAV and a head end control unit in wireless communication with the UAV. A method of RF spectrum identification and mapping includes collecting RF data by the UAV within an area of operation, determining location data within the area of operation using a global positioning system (GPS) located on the UAV, and mapping the RF data of the area of operation using the location data.

An unmanned aerial vehicle (UAV) has a first radio configured to operate on one of a plurality of radio frequency (RF) channels, a processing and management application program interface (API), and a controller. A system for active radio frequency (RF) channel switching includes the UAV and a head end control unit in wireless communication with the UAV. A method of RF spectrum identification and mapping includes collecting RF data by the UAV within an area of operation, determining location data within the area of operation using a global positioning system (GPS) located on the UAV, and mapping the RF data of the area of operation using the location data.