In an example of the described techniques, a wireless communication system includes first memory, second memory, a first microcontroller, and a second microcontroller. The first microcontroller manages drivers for a wireless transceiver and direct data movement between the wireless transceiver and the first memory. The second microcontroller communicates with other systems that generate application data to be wirelessly transmitted. The application data to be wirelessly transmitted is stored in the second memory. Additionally, the second microcontroller direct data movement between the second memory and the first memory.

In an example of the described techniques, a wireless communication system includes first memory, second memory, a first microcontroller, and a second microcontroller. The first microcontroller manages drivers for a wireless transceiver and direct data movement between the wireless transceiver and the first memory. The second microcontroller communicates with other systems that generate application data to be wirelessly transmitted. The application data to be wirelessly transmitted is stored in the second memory. Additionally, the second microcontroller direct data movement between the second memory and the first memory.

A battery pack has a battery connection assembly for connecting to an electric motor with at least one lithium-based rechargeable cell therein and associated means for turning the at least one lithium-based rechargeable cell ON or OFF. The battery pack is configured to store a reserve within the at least one lithium-based rechargeable cell that is sufficient to start the engine electric motor. The battery pack can be activated by the associated means for turning the at least one lithium-based rechargeable cell ON or OFF to access the reserve to start the engine electric motor.

A battery pack has a battery connection assembly for connecting to an electric motor with at least one lithium-based rechargeable cell therein and associated means for turning the at least one lithium-based rechargeable cell ON or OFF. The battery pack is configured to store a reserve within the at least one lithium-based rechargeable cell that is sufficient to start the engine electric motor. The battery pack can be activated by the associated means for turning the at least one lithium-based rechargeable cell ON or OFF to access the reserve to start the engine electric motor.

A network element one or more network ports, network time circuitry and packet processing circuitry. The network ports are configured to communicate with a communication network. The network time circuitry is configured to track a network time defined in the communication network. In some embodiments the packet processing circuitry is configured to receive a definition of one or more timeslots that are synchronized to the network time, and to send outbound packets to the communication network depending on the timeslots. In some embodiments the packet processing circuitry is configured to process inbound packets, which are received from the communication network, depending on the timeslots.

An efficient return channel spectrum utilization technique for communication systems supporting adaptive spread spectrum. Requests for bandwidth allocation using a spread factor are analyzed to determine if there are any channels capable of supporting the spread factor. The request is acknowledged if at least one channel is capable of supporting the request. Adjacent channels required to accommodate the requested spread factor are reserved, and additional bandwidth requests are allocated on non-reserved channels.

A method of controlling communications within a wireless communications network is provided. The method comprises receiving, at a first infrastructure equipment acting as a donor node connected to a core network part of a wireless communications network, signals representing data from one or more others of infrastructure equipment, the data having been received at the one or more others of the infrastructure equipment from one or more communications devices or from other infrastructure equipment, and transmitting, by the first infrastructure equipment, the data from the one or more others of the infrastructure equipment to the core network part of the wireless communications network. At least one of the infrastructure equipment uses at least one spectral efficiency enhancing technique to receive the signals, the at least one spectral efficiency enhancing technique allowing the at least one infrastructure equipment to receive the signals in the backhaul communications link.

Technology for a multi-repeater system including wireless transmission of power from a first repeater to a second repeater is disclosed. A first and second repeater can be disposed opposite each other about a structural element. Wireless power can be transmitted from the first repeater through the structural element to the second repeater for use by the second repeater.

Embodiments of this application provide a transmission direction configuration method, a device, and a system, and relate to the field of communications technologies. A specific solution is as follows: a terminal device receives first indication information from a network device, the first indication information is used to indicate a configuration of uplink and downlink transmission directions, the configuration is used to describe types, a number, and distribution of resource elements comprised in one period, the resource granularity comprises a time domain granularity, the time domain granularity comprises (OFDM) symbol, the types of the resource elements comprise at least one of an uplink resource element, a downlink resource element, or a switch resource element between the downlink resource element and the uplink resource element; and performs information transmission indicated by the first indication information, of the uplink and/or downlink transmission directions.

Apparatus and methods for providing enhanced coverage in a quasi-licensed wireless system using a reduced-cost base station apparatus. In one embodiment, the base station is configured to utilize quasi-licensed 3.55-3.70 GHz CBRS (Citizens Broadband Radio Service) GAA and PAL spectrum, and employs a power amplifier sharing arrangement in its transmitter chain(s), along with multi-sector antenna elements. A scheduling algorithm operative on the base station generates sector-specific weights which are used to allocate the shared power amplifier(s) between the different sectors. Advantageously, design and production costs of the base station are reduced through sharing of comparatively expensive amplifier and transmitter chain components, thereby allowing for commoditization of the base station for mass distribution.