Examples described herein mitigate adjacent channel interference for dual radios of a network device. Examples described herein may associate, by a network device, a first client device with a first radio of the network device, associate, by the network device, a second client device with a second radio of the network device, determine that the first and second client devices are within a steering threshold, and based on the determination that the first and second client devices are within the steering threshold, steer, by the network device, the second client device from the second radio to the first radio. Examples described herein may communicate, using the first radio of the network device, with the first and second client devices.

Examples described herein mitigate adjacent channel interference for dual radios of a network device. Examples described herein may associate, by a network device, a first client device with a first radio of the network device, associate, by the network device, a second client device with a second radio of the network device, determine that the first and second client devices are within a steering threshold, and based on the determination that the first and second client devices are within the steering threshold, steer, by the network device, the second client device from the second radio to the first radio. Examples described herein may communicate, using the first radio of the network device, with the first and second client devices.

Systems and methods for managing communications between edge devices and cloud devices over a first network (e.g., a private network such as a private 5G network) and a second network (e.g., a public network such as a public 5G network), involving monitoring an amount of traffic data in the first network. When the amount of traffic data exceeds a predetermined value, systems and methods further involve selecting one or more applications executing in a device of the first network; migrating the selected one or more applications from the first network to the second network; and changing a destination address of data communications associated with the selected one or more applications from the device in the first network to another device in the second network; wherein the selecting the one or more applications is conducted based on compute resources required for executing each one or more applications per traffic data.

Systems and methods for managing communications between edge devices and cloud devices over a first network (e.g., a private network such as a private 5G network) and a second network (e.g., a public network such as a public 5G network), involving monitoring an amount of traffic data in the first network. When the amount of traffic data exceeds a predetermined value, systems and methods further involve selecting one or more applications executing in a device of the first network; migrating the selected one or more applications from the first network to the second network; and changing a destination address of data communications associated with the selected one or more applications from the device in the first network to another device in the second network; wherein the selecting the one or more applications is conducted based on compute resources required for executing each one or more applications per traffic data.

A method for adjusting cell measurement, a user equipment (UE), and a storage medium are provided. The method includes: determining wireless communication throughput of the UE is lower than a threshold, and adjusting a cell measurement result of a serving cell, where the adjusted cell measurement result is used to steer the UE to a neighbor cell.

A method includes receiving, from a plurality of user devices, a plurality of requests to transmit over a wireless fidelity (WiFi) network and in response to determining that the WiFi network cannot support the plurality of requests, determining that a first request of the plurality of requests should be supported by a cellular network. The method also includes instructing a first user device of the plurality of user devices that communicated the first request to perform transmissions corresponding to the first request over the cellular network.

A method includes receiving, from a plurality of user devices, a plurality of requests to transmit over a wireless fidelity (WiFi) network and in response to determining that the WiFi network cannot support the plurality of requests, determining that a first request of the plurality of requests should be supported by a cellular network. The method also includes instructing a first user device of the plurality of user devices that communicated the first request to perform transmissions corresponding to the first request over the cellular network.

A method and apparatus of routing a call in a femtocell network are disclosed. In one example call routing method, a call is originated from the mobile station via a femtocell access point and the call is transmitted to a femtocell gateway, a mobile switching center and a carrier gateway server and onto an enterprise gateway server to obtain policy information. A routing policy is determined based on the obtained policy information and the call is routed to its destination based on the routing policy. The call may be routed via local media from a femtocell access point directly to the enterprise gateway server. The call routing procedures may implement the Iuh protocol and/or the session initiation protocol (SIP) for call signaling in the femtocell network. Call routing may be performed in a wireless cellular communications network or an enterprise network environment.

A processor-implemented method includes receiving, from a mobile device, transmission information corresponding to an audio data transmission associated with an audio data packet loss of one or more audio data packets. The processor determines, based at least in part on the transmission information, a geographic region associated with a wireless communication network transceiver. The processor further determines an average audio data packet loss rate associated with the geographic region and a correlation between the audio data packet loss and at least one key performance indicator (KPI). The KPI is indicative of the audio data transmission. Based at least in part on (i) the average audio data packet loss rate and (ii) the correlation between the audio data packet loss and the at least one KPI, the processor generates a handover instruction comprising at least one threshold value for transitioning control from a first cell channel to a second cell channel.

Disclosed are techniques for wireless communication that over come problems associated with conventional approaches including load balancing and handover efficiency issues. In one aspect a wireless communication technique takes into account the load of a donor gNB before a relay decides to reselect from one donor gNB to another. In another aspect, a wireless communication technique ensures that relays are handed over to base stations that will be able to serve the relay as the mobile relay continues to follow its expected path (e.g. streets or tracks).