Sensors within sensor node networks may communicate bio-event or other types of measurement results/decisions between each other using signal transmission variations. Each sensor node within a network and between networks may transmit and receive signals. A sensor node may scale a signal transmission power in a manner that is proportional to a confidence level of a decision or measurement about an event being detected. Each sensor node will receive transmissions from neighboring nodes, and can refine an estimate about an occurrence of the event at its location based on received signal strengths, for example.

A method and system for managing traffic in a network. For each label switch path of at least two logical switch paths, logical paths are identified. Each label switch path begins at a first provider edge and ends at a second provider edge. Most recent data received from the first provider edge is transmitted to the second provider edge via a selected logical path.

A signal interface unit for a distributed antenna system includes a channelized radio carrier interface configured to communicate an uplink channelized radio carrier for a radio frequency carrier to a channelized radio carrier base station interface; an antenna side interface configured to receive an uplink digitized radio frequency signal from the distributed antenna system communicatively coupled to the antenna side interface; and a signal conversion module communicatively coupled between the channelized radio carrier interface and the antenna side interface and configured to convert between the uplink digitized radio frequency signal and the uplink channelized radio carrier at least in part by adjusting at least one uplink attribute of the uplink digitized radio frequency signal received from the distributed antenna system to comply with requirements of the channelized radio carrier base station interface.

A modular lighting and ancillary component apparatus and system utilizes standard USB protocol and connections between modules so that different modules can be selected, installed, and changed by a user. The USB-C protocol is preferably used, which may permit bidirectional functionality between connected modules in an apparatus and potentially between separate apparatuses. The USB-PD protocol may also be employed so that a greater range of items can be powered. The apparatus includes a base module, and may include one or more ancillary modules and/or a light-emitting module.

Disclosed herein is a wireless mesh network comprised of ultra-high-capacity nodes that are capable of establishing ultra-high-capacity links (e.g., point-to-point or point-to-multipoint bi-directional communication links) using a millimeter wave spectrum, including but not limited to 28 Ghz, 39 Ghz, 37/42 Ghz, 60 Ghz (including V band), or E-band frequencies, as examples. The higher capacity and/or extended range of these ultra-high-capacity nodes/links may be achieved via various advanced signal processing techniques. Further, these ultra-high-capacity nodes/links may be used in conjunction with other types of point-to-point and/or point-to-multipoint links to build a multi-layer wireless mesh network.

Disclosed herein is a wireless mesh network comprised of ultra-high-capacity nodes that are capable of establishing ultra-high-capacity links (e.g., point-to-point or point-to-multipoint bi-directional communication links) using a millimeter wave spectrum, including but not limited to 28 Ghz, 39 Ghz, 37/42 Ghz, 60 Ghz (including V band), or E-band frequencies, as examples. The higher capacity and/or extended range of these ultra-high-capacity nodes/links may be achieved via various advanced signal processing techniques. Further, these ultra-high-capacity nodes/links may be used in conjunction with other types of point-to-point and/or point-to-multipoint links to build a multi-layer wireless mesh network.

A server coupled to wireless transceivers wirelessly communicating user data on corresponding ones of a plurality of wireless local area networks (WLAN) is disclosed. The server comprises: a memory, and a processor. The memory to store executable instructions. The processor is coupled with the memory, wherein the processor, responsive to executing the executable instructions, performs operations comprising: identifying wireless transceivers and access privileges requested by each of a plurality of WiFi service vendors; opening a control portal between each WiFi service vendor and the corresponding wireless transceivers identified in the identifying act; and arbitrating access by each WiFi service vendor to the corresponding identified wireless transceivers to avoid interruption of the wireless user data communications on corresponding ones of the WLANs.

Embodiments contemplate methods and systems for determining and communicating channel state information (CSI) for one or more transmission points (or CSI reference signal resources). Embodiments further contemplate determining transmission states may include applying at least one CSI process for channel state information (CSI) reporting. Embodiments also contemplate aperiodic and/or periodic reporting of one or more report types (e.g., rank indicator (RI)) of CSI, perhaps based on one or more reporting modes that may be configured for each of the one or more CSI process.

The present disclosure provides a global communication network system based on a micro base station and edge computing, including at least one micro base station. Each micro base station includes an edge computing center, a business network element and a micro base station access network. The comprehensive carrying capability of a wireless network, the regional resource sharing capability, the computing capability of an access terminal, the flexible application capability of the access terminal and user experience of extremely low delay are improved.

A system (100) for communicating data packets is provided. The system may include a first device (102) and a second device (104). The first device (102) may include a first processor (112) and a plurality of WWANs (118). The first processor (112) may execute a first MPTCP (204) and a plurality of first VPNs (206). The first device (204) may be configured to receive and segregate a stream of packets of data into a plurality of data blocks (Db). The first MPTCP (204) and the plurality of WWANs (118) may coordinate to provide multiple data paths based on the bandwidth of each of the plurality of WWANs (118) for transmitting the plurality of data block (Db). The plurality of data blocks may be received by the second device (104) to be further processed and sent to a desired destination.