An exemplary system, method and computer-accessible medium for determining a degradation(s) of a wireless link(s) can be provided, which can include, for example, periodically determining a wireless channel quality of the wireless link(s) between a sender and a receiver, recording a history of the wireless channel quality, determining whether a plurality of diffractive pulses are present based on the history and determining the degradation(s) based on the presence of the plurality of diffractive pulses. The wireless channel can be in a beam-forming direction. The degradation(s) can be an impending degradation.

Systems and methods are provided for enhancing cellular network coverage. In order to enhance network coverage, churn data is correlated with the measured coverage data for the multiple locations in the cellular network. Based on the correlation, a network readiness status in the multiple locations is determined. Network resources are then deployed to any of the multiple locations determined to have a network readiness status of not ready.

Systems and methods are provided for enhancing cellular network coverage. In order to enhance network coverage, churn data is correlated with the measured coverage data for the multiple locations in the cellular network. Based on the correlation, a network readiness status in the multiple locations is determined. Network resources are then deployed to any of the multiple locations determined to have a network readiness status of not ready.

An information processor according to one aspect of the present disclosure includes a first acquisition unit configured to acquire desire information regarding an area setting of a predetermined service, including at least desired area information, provided using a second radio system that shares all or a part of a frequency band used by a first radio system, a second acquisition unit that acquires area information regarding another service that uses or is allocated to a predetermined frequency band used by the predetermined service, a calculation unit configured to perform calculation regarding inter-area interference from an area specified by the desired area information to an area of the another service; and a generation unit configured to generate permitted area information regarding an area in which the predetermined service is permitted based on a calculation result of the inter-area interference.

Various embodiments comprise systems, methods, and apparatus for a radio access network (RAN) Network Repository Function (RNRF) configured to receive gNB feature/capability information from gNB formed by network RAN, store the received gNB feature/capability information, and provide gNB feature/capability information to requesting core network nodes or functions so that these nodes/functions may adapt/configure their operation or the services they provide in response to the gNB capabilities.

Dynamic network resource management in a wireless communications system (WCS) is disclosed. The WCS includes multiple radio access network (RAN) remote units each configured to communicate a radio frequency (RF) signal(s) in a respective one of multiple coverage cells. The multiple coverage cells can be associated with a number of cell groups, with each of the cell groups including one or more of the multiple coverage cells. Given that all of the cell groups are operating based on a set of network functions configured for the WCS, the WCS further employs a network device to dynamically determine a set of sharable network functions and share the set of sharable network functions among the cell groups. By dynamically sharing the sharable network functions across the cell groups, it is possible to maximize throughput in each of the cell groups based on the set of sharable network functions.

Dynamic network resource management in a wireless communications system (WCS) is disclosed. The WCS includes multiple radio access network (RAN) remote units each configured to communicate a radio frequency (RF) signal(s) in a respective one of multiple coverage cells. The multiple coverage cells can be associated with a number of cell groups, with each of the cell groups including one or more of the multiple coverage cells. Given that all of the cell groups are operating based on a set of network functions configured for the WCS, the WCS further employs a network device to dynamically determine a set of sharable network functions and share the set of sharable network functions among the cell groups. By dynamically sharing the sharable network functions across the cell groups, it is possible to maximize throughput in each of the cell groups based on the set of sharable network functions.

Aspects described herein provide a computer implemented radio frequency propagation simulation tool to allow the simulation of radio frequency propagation across a topographic area which has been very finely mapped in three dimensions to include possible obstructions to high frequency radio waves. A computer implemented RF propagation simulation tool may identify any possible obstructions one edge of which may lie in a simulated RF propagation path between two points, and apply an edge based RF diffraction model (a so-called “knife edge diffraction” model) thereto to simulate the RF propagation around the obstruction. In some aspects, a computer implemented RF propagation simulation tool may identify possible obstructions which in their entirety lie within the width of a simulated RF propagation path, and apply a further diffraction model (a so-called “shield diffraction” model) thereto to simulate the RF propagation around the obstruction. The results of the simulations of RF propagation can be graphically overlaid onto a map or other topographic image for display to a user.

Wireless communication is provided over an extended distance using a line or a series of drones traveling along a transmission path between a transmitter and a receiver. The transmitter sends a data signal to a first drone that is within range of the transmitter. The first drone sends the data signal to an adjacent drone in the line of drones which retransmits the data signal to the next drone in line. The data signal is transmitted between drones until it reaches a final drone within range of the receiver. The final drone transmits the data signal to the receiver. As the drones travel along the transmission path, new drones are launched from a location within range of the transmitter to replace drones that land after transmitting a data signal to the receiver.

Wireless communication is provided over an extended distance using a line or a series of drones traveling along a transmission path between a transmitter and a receiver. The transmitter sends a data signal to a first drone that is within range of the transmitter. The first drone sends the data signal to an adjacent drone in the line of drones which retransmits the data signal to the next drone in line. The data signal is transmitted between drones until it reaches a final drone within range of the receiver. The final drone transmits the data signal to the receiver. As the drones travel along the transmission path, new drones are launched from a location within range of the transmitter to replace drones that land after transmitting a data signal to the receiver.