Systems and methods of the present disclosure enable mesh network capacity management via network metering using a processor an integrated roofing mesh network node in a mesh network to receive and transmit data packets in the mesh network. Each data packet includes a source address, a destination address, and a payload of data. The processor determines passthrough traffic including a subset of data packets routed between radio nodes of the mesh network through the gateway based on the source address and the destination address of each data packet and an address associated with the gateway. The processor determines a passthrough data capacity based on the payload of each data packet in the subset and determines a metric based on the passthrough data capacity to signify an amount of mesh network bandwidth provided by the integrated roofing mesh network node.

Disclosed herein are systems, methods, and devices for time of arrival estimation in wireless systems and devices. Devices include a packet detector configured to identify a data packet included in a received signal having a symbol frequency. Devices also include a time stamping unit configured to generate an initial time stamp in response to the packet detector identifying the data packet. Devices further include an IQ capture unit configured to acquire a plurality of IQ samples representing phase features of the received signal. Devices additionally include a processing unit that includes one or more processors configured to generate an estimated time of arrival based on the initial time stamp and the plurality of IQ samples.

Systems and methods of the present disclosure enable mesh network capacity management via network metering using a processor an integrated roofing mesh network node in a mesh network to receive and transmit data packets in the mesh network. Each data packet includes a source address, a destination address, and a payload of data. The processor determines passthrough traffic including a subset of data packets routed between radio nodes of the mesh network through the gateway based on the source address and the destination address of each data packet and an address associated with the gateway. The processor determines a passthrough data capacity based on the payload of each data packet in the subset and determines a metric based on the passthrough data capacity to signify an amount of mesh network bandwidth provided by the integrated roofing mesh network node.

A method and system for networking of spliced building blocks, and the spliced building blocks applicable to wireless networking are provided. The method includes a step of first network establishment: according to a first configuration instruction, instructing mutual networking among communication nodes of spliced building blocks belonging to a first set to obtain a first network, where the first configuration instruction comes from a locality or an external intelligent terminal; and a step of second network establishment: according to a second configuration instruction, instructing mutual networking among communication nodes of spliced building blocks belonging to a second set in the first network to obtain a second network, where the second configuration instruction is transmitted by the first network, both the first network and the second network are wireless networking networks, and the data transmission efficiency of the second network is higher than the data transmission efficiency of the first network.

A method of data transfer to a plurality of devices on a mesh network includes receiving bulk data at a proxy device in the mesh network; storing, at the proxy device, the bulk data; confirming, to a source of the bulk data, that the bulk data is received; after confirming that the bulk data is received, performing a transfer of the bulk data packet-by-packet to at least one other node in the mesh network; and performing a unicast communication to identify missing packets. The transfer can be or include a cascade transfer in which the data is transferred packet-by-packet to a next available node in the mesh network that itself passes a received packet to its next available node in the mesh network.

A radio module for a wireless communication node in a wireless mesh network includes a reflectarray antenna having a plurality of antenna elements. Each antenna element of the plurality of antenna elements is configured to receive an incident signal, apply one of two phase shifts to the incident signal, and radiate the phase-shifted signal. The radio module further includes a radio frequency (RF) module comprising a single RF chain configured to feed the incident signal to the plurality of antenna elements in the reflectarray antenna, as well as a control unit that is configured to control which of the two phase shifts is applied by each antenna element in the reflectarray antenna.

A wireless communication node within a mesh-based communication system includes wireless mesh equipment that is configured to establish and communicate over one or more bidirectional wireless links with one or more other wireless communication nodes of the mesh-based communication system. The wireless communication node further includes a multi-tier storage architecture that is configured to store data at the wireless communication node. The multi-tier storage architecture includes at least (i) a first tier of one or more storage units that is designated for storage of a first class of data, and (ii) a second tier of one or more storage units that is designated for storage of a second class of data that differs from the first class of data.

In a communication system having a plurality of user equipment (UE) devices that are operating in a contention based mode for device-to-device (D2D) communication, each UE device transmits a preferred transmission indicator when a condition for preferred transmission is met at the UE device. If a UE device receives a preferred transmission indicator, the UE device delays transmission of a D2D scheduling assignment (SA) to contend for communication resources for D2D communication. The length of the delay can be based on a number of preferred transmission indicators that are received. The preferred transmission indicator is based on a buffer size in one example.

A communication apparatus for inter-vehicular communication according to the present invention includes: a network state estimating unit configured to estimate network state information indicating a current network state based on driving information and channel state information of neighboring vehicles; a network access controller configured to control whether to transmit a message based on the network state information; a transmission scheduler configured to control a transmission time point of the message based on the network state information; and a transmission buffer unit configured to delay transmission of the message according to the control of the transmission time point of the transmission scheduler.

A forwarding entry generation method includes sending, by a controller, a plurality of resource allocation request messages to a plurality of network devices in a network slice, to trigger the plurality of network devices to allocate resources, where the resource allocation request message includes an identifier of the network slice and a resource that needs to be allocated by a corresponding network device to the network slice; receiving, by the controller, a plurality of resource allocation response messages including the identifier of the network slice and a segment identifier of a corresponding network device, and a resource allocated by each device belongs to the network slice; and generating, by the controller, a forwarding table corresponding to the network slice, where the forwarding table includes a forwarding entry for arriving at a network device in the network slice.