Systems and methods described herein provide an intelligent MEC resource scheduling service. A network device in a MEC network stores, in a memory, threshold values indicating overload conditions for resource usage by a first MEC cluster; monitors resource usage in the first MEC cluster; determines, based on the monitoring, when one of the threshold values is reached; identifies available resources in a second MEC cluster; and re-directs, based on the identifying, at least some of the resource usage from the first MEC cluster to the second MEC cluster.

An information handling system operating a mesh network link aggregation optimization system may comprise a plurality of mesh access points, and one or more client devices connected via a plurality of wireless links forming a mesh wireless network. A processor may execute code instructions to generate a congestion score for each of the links based on measured traffic and quality of service of each of the links, determine the congestion score for a congested link does not meet a preset congestion threshold value, determine a location within the mesh wireless network in which to aggregate links between two mesh access points, based on availability of one or more radios, and transmit an instruction to one of the plurality of mesh access points to aggregate two or more links at the network layer at the determined location for simultaneous transmission on a single band.

Techniques are described for enhancing wireless communication using millimeter wave (mmW) communication and mesh network topology. One method includes transmitting data to a first wireless device via a first mmW communication beam from a base station, determining that a performance level of the first mmW communication beam is below a threshold value based on transmitting the data, and communicating with the first wireless device over a transmission route based on a performance level of a second mmW communication beam. In some examples, the transmission route includes a first segment that includes the second mmW communication beam and a second segment that includes a wireless mesh network.

Systems and methods are provided for in-vehicle data-driven connectivity optimization in a network of moving things. An on-board unit configured for deployment in a vehicle may obtain, during operations in an area of the network of moving things, connectivity-related data relating to coverage within the area, and generate or update, based on processing of the obtained connectivity-related data, a networking decision model. The networking decision model is configured for optimizing connectivity to the one or more access points in or associated with the network of moving things. The networking decision model may be shared with other on-board units deployed in other vehicles and/or with a Cloud-based network node in the network.

The present invention relates to a receiver-centric transmission system for IoT systems, such as lighting networks, with combo protocol radio chips that share a single radio front-end for two or more transmission protocols of different network technologies while preventing unacceptable performance degradations in one or both protocol modes. The receiver-centric approach allows implementation of two networks with acceptable performances on one single radio chip per node rather than requiring two radio chips per node.

A method including receiving, by a device in communication with a first endpoint and a second endpoint in a mesh network, a first communication from the first endpoint and a second communication from the second endpoint; selectively comparing, by the device, first observed connection state information associated with the first communication with the stored connection state information associated with outgoing communications transmitted by the device, and second observed connection state information associated with the second communication with the stored connection state information; and selectively processing, by the device, the first communication based at least in part on a result of selectively comparing the first observed connection state information with the stored connection state information, and the second communication based at least in part on a result of selectively comparing the second observed connection state information with the stored connection state information. Various other aspects are contemplated.

A method including storing, by a first device in a mesh network, stored connection state information associated with an outgoing communication transmitted by the first device; determining, by the first device, observed connection state information based at least in part on receiving an incoming communication from a second device in the mesh network; comparing, by the first device, the observed connection state information with the stored connection state information; and selectively processing, by the first device, the incoming communication based at least in part on a result of the comparing. Various other aspects are contemplated.

Techniques are described for enhancing wireless communication using millimeter wave (mmW) communication and mesh network topology. One method includes transmitting data to a first wireless device via a first mmW communication beam from a base station, determining that a performance level of the first mmW communication beam is below a threshold value based on transmitting the data, and communicating with the first wireless device over a transmission route based on a performance level of a second mmW communication beam. In some examples, the transmission route includes a first segment that includes the second mmW communication beam and a second segment that includes a wireless mesh network.

A first device in a communication network receives from at least one second device in the communication network, a first request for acquiring a token, the token being permission for communicating with a third device. Based on the first request, a device from the at least one second device and the first device as a communication device is selected for providing a communication service to the third device in the communication network; and the token is transmitted to the communication device. The communication device receives the token for communicating with the third device. Other devices receive key information associated with communication of the third device from the first device, and monitor data associated with the communication of the third device.

Techniques are provided for offloading a wireless local area network (WLAN) scanning process, from the WLAN radio of the device to a Bluetooth radio, to identify information regarding the WLAN mobile environment. By offloading the WLAN scanning process to the Bluetooth radio (e.g., to a Bluetooth Low Energy (BLE) radio), traffic disruptions for active WLAN links is reduced. The techniques further provide for the creation of an ad-hoc network using the Bluetooth interface between multiple STAs and one or more access points (APs), each exchanging information regarding the WLAN environment over the respective Bluetooth radios. The ad-hoc Bluetooth network allows each device on the network to be more aware of the mobile environment. The increased aware may allow the leader AP to optimize AP-Client mapping table that maps the one or more STAs in the ad-hoc network to the one or more APs for improved load balancing.