An energy conservation management method includes selecting, by a policy server, a target scenario model from a plurality of scenario models based on a plurality of scenario attribute values of a target network, and configuring, by the policy server, a network device in the target network based on an energy conservation policy of the target scenario model. At least one of the plurality of scenario attribute values is an attribute value of a scenario attribute related to a network power consumption of the target network. The at least one of the plurality of scenario attribute values includes a plurality of attribute values of a corresponding scenario attribute, wherein each of the plurality of attribute values is collected at a different time from other attribute values of the plurality of attribute values that are collected at different times.

Aspects described herein relate to managing coexistence of multiple radio access technology (RAT) components in a device. Information related to an upcoming time period can be sent to a first radio access technology (RAT) component from a second RAT component. The first RAT component can select a resource to transmit a first RAT packet to minimize collision with the upcoming time period of the second RAT.

A bridge for bridging mobile communications may include a donor bridge node and/or one or more service bridge nodes. The donor bridge node may be configured to connect to a base station pooling location comprising a plurality of cell signals, determine for each cell signal a service link carrier frequency in a service link frequency band and a bridge link carrier frequency in a bridge link frequency band, associate each cell signal and the determined carrier frequencies in the service link frequency band and in the bridge link frequency band with the one or more service bridge nodes, and communicate each cell signal at the bridge link carrier frequency of the cell signal. The service bridge nodes may communicate with the donor bridge node at the carrier frequency of the bridge link frequency band and with user equipment in the service link carrier frequency of the service link frequency band.

A communication prediction-based energy saving method and an apparatus, the method including receiving, by a first radio access network device, from a second network device a communication prediction result that includes a communication period, traffic, a periodic communication indication, or a burst communication indication, where the traffic represents a predicted uplink or downlink data traffic volume, where the periodic communication indication represents whether communication predicted to occur is periodic, and when the communication predicted to occur is periodic, a communication interval, or the uplink or downlink data traffic volume of the periodic communication, where the burst communication indication represents whether the communication predicted to occur is bursty, and, when the communication predicted to occur is bursty, a time point, the uplink or downlink data traffic volume of the burst communication, and performing, by the first radio access network device, an energy saving operation based on the communication prediction result.

A bridge may include a donor bridge node and one or more service bridge nodes. The donor bridge node may be configured to connect to a base station pooling location comprising a plurality of cell signals, determine for each cell signal a service link carrier frequency in a service link frequency band and a bridge link carrier frequency in a bridge link frequency band, associate each cell signal and the determined carrier frequencies in the service link frequency band and in the bridge link frequency band with the one or more service bridge nodes, and communicate each cell signal at the bridge link carrier frequency of the cell signal. The service bridge nodes may communicate with the donor bridge node at the carrier frequency of the bridge link frequency band and with user equipment in the service link carrier frequency band of the service link frequency band.

A method of reducing a power consumption of wireless communication circuitry of an edge device according to one embodiment includes determining a delivery traffic indication map (DTIM) interval of a wireless access point communicatively coupled to the edge device via the wireless communication circuitry of the edge device and adjusting a wake-up interval of the wireless communication circuitry of the edge device based on the DTIM interval to reduce the power consumption of the wireless communication circuitry of the edge device.

A backscatter tag device includes, in part, a receiver configured to receive a packet conforming to a communication protocol defining a multitude of codewords, a codeword translator configured to translate at least a first subset of the multitude of codewords disposed in the packet to a second multitude of codewords defined by the protocol in response to a data the backscatter tag is invoked to transmit, and a transmitter configured to transmit the packet supplied by the codeword translator at a frequency different than the first frequency at which the packer is received. The communication protocol may optionally be the 802.11 g/n, ZigBee or the Bluetooth communication protocol.

A method is disclosed for a centralized unit (CU) of a wireless communication network, wherein the CU is associated with each of one or more remote units (RU) of the wireless communication network via a respective communication interface. The CU is adapted to operate in one of a plurality of modes including at least a normal operation mode and a power saving operation mode, and the normal operation mode defines a plurality of functions to be performed by the CU. The method comprises (when the CU is in the normal operation mode) determining that a traffic load associated with the one or more RU fulfills a power saving operation criterion, configuring—via the respective communication interface each of the RU for autonomous operation, whereby each of the RU is configured to execute at least one of the plurality of functions, and transferring from the normal operation mode to the power saving operation mode. Corresponding method for a remote unit, computer program products, network node, and arrangements for CU and RU, respectively, are also disclosed.

A sensor device for conducting electronic transactions from a vehicle including a housing including an RFID circuit operably connected to an RFID antenna, a short range communication device, the RFID circuit and short range communication device operably connected to a processor, and a power supply. The sensor device is wirelessly connectable to a mobile communication device via the Bluetooth chip and the mobile communication device runs a software application. The RFID antenna is adapted to receive a wireless signal from a transmitter. Responsive to the wireless signal, the processor causes the short range communication device to wirelessly communicate with the mobile communication device to initiate a transaction.

This disclosure provides systems, methods, and apparatus, including computer programs encoded on computer-readable media, for leveraging a resource management protocol under an integrated access and backhaul (IAB) framework for power savings. In some aspects, a first node (such as an IAB node) may receive resource management information from a second node (such as an IAB donor). The resource management information may indicate an unavailable type of resource management configuration for the first resource associated with the first node. The first node may schedule a power save mode during the first resource having the unavailable type of resource management configuration for power savings. The first resource may be a time domain resource, a frequency domain resource, or a spatial domain resource. In some aspects, the first node may restrict both non-exempt and exempt communications during the first resource when the first node is in the power save mode.