According to certain embodiments, a method in a wireless device (110) includes transmitting a protocol data unit (PDU) or segment of a PDU on a first link and transmitting the PDU or the segment of the PDU on a second link. One or more retransmissions of the PDU or the segment of the PDU are scheduled on the second link. A positive acknowledgment is received from a receiver. The positive acknowledgement indicates a successful receipt of the PDU or the segment of the PDU on the first link. In response to receiving the positive acknowledgement, the one or more retransmissions of the PDU or the segment of the PDU on the second link are cancelled.

A Bluetooth communication system includes: an inquirer-side Bluetooth device arranged to operably generate and transmit a Bluetooth inquiry request; and a requester-side Bluetooth device arranged to operably receive and parse the Bluetooth inquiry request, and to operably generate and transmit a Frequency Hop Synchronization (FHS) packet containing a requester-side Bluetooth address and an Extended Inquiry Response (EIR) packet containing an auto-pairing request to the inquirer-side Bluetooth device. The inquirer-side Bluetooth device conducts an auto-pairing procedure with the requester-side Bluetooth device according to the contents of FHS packet and the EIR packet, but the inquirer-side Bluetooth device and the requester-side Bluetooth device does not switch to operating modes for transmitting or receiving Bluetooth advertising packets before conducting the auto-pairing procedure.

A method to jointly perform beam management, synchronization, and L1 measurements using a single synchronization signal block (SSB) burst in NR systems is proposed to improve data rate and to reduce power consumption. In a scheduling based SSB method, a UE is scheduled to perform either beam management or synchronization and L1 measurements alternatively. In a joint SSB method, a UE performs beam management, synchronization, and L1 RSRP/SNR measurements within a single SSB burst simultaneously. The UE can dynamically switch between the two SSB methods based on predefined conditions. Further, multiple joint SSB modes are introduced for the joint SSB method, where either 3 OFDM symbols or 4 OFDM symbols of each SSB burst are used. UE can dynamically switch among the joint SSB modes depending on contamination level on the OFDM symbol carrying PSS.

Methods, systems, and devices for wireless communications are described. A device may be configured to support multi-beam, or multi-panel operations, or both which may allow multiple sidelink transmissions to occur simultaneously. In some cases, flexible beam-management for the beamformed sidelink communications is implemented to manage the beams. A transmitting UE may indicate transmission beam information to the base station that the base station may use to schedule sidelink transmissions as part of a beam management procedure. The beam management procedure may allow a transmitting UE to update transmission beam information based on the mobility of the sidelink UEs and other environmental factors. In some cases, beam management includes a beam training procedure that may be implemented to refine the sidelink beams, where support for multi-panel and multi-beam operation may allow for multiple beams to be trained simultaneously.

Method and systems are provided for receiving and transmitting signals over a time division duplex communication path (the “Path”). Operations may include sending a first signal via an uplink portion of the Path, and receiving a second signal via a downlink portion of the Path. The Path operates over a first band having a first frequency range and during a communication time including an uplink period (TU) and a downlink period (TD). The uplink portion is sent during the uplink period, uses a first portion of the first frequency range and is disposed between a first uplink guard band portion and a second uplink guard band portion. The guard bands are allocated from a second portion and a third portion of the first band. The first band is disposed between a second band, providing a second communication path, and a third band providing an FDD communication path.

A server device includes a memory and processor. A vehicle identification number (VIN) is stored in the memory. The VIN is associated with connection information for a vehicle associated with the VIN. The processor executes A VIN matcher stored in the memory, and denies a request for connection information in response to a mismatch between a supplied VIN from a connecting device and the VIN stored in memory. The processor executes a network connector stored in the memory, and sends connection information to a connecting device in response to a match between the supplied VIN from the connecting device and the VIN stored in memory. The connection information is sent through the network connection using a first communication protocol and contains information for the connecting device to connect to the vehicle through direct pairing using a second communication protocol.

A hands-free device enables a hands-free call by being wirelessly connected to a mobile phone. The hands-free device incudes a hardware processor configured to: perform a control related to data transfer using a transfer protocol for implementing transfer of history data including incoming call history data and outgoing call history data, and phone book data stored in the mobile phone when the mobile phone is in a wireless connection area; receive the history data and the phone book data from the mobile phone through communication using the transfer protocol; and store the history data and the phone book data that are received. The hardware processor is configured to perform the control to transfer the history data prior to the phone book data.

A multi-functional vehicle helmet, having a helmet assembly with an exterior shell and an interior shell having protective foam in between. The exterior shell has a transceiver for wireless communications embedded therein. Further having an audio video interleave recording device, and a multifunctional knob assembly having first and second multifunctional knobs, skipping buttons, and tracking buttons. Further having a microphone assembly, and a stereo speaker assembly with at least one speaker embedded in the interior shell. Further having a liquid crystal display, at least one secure digital expansion slot, and a battery assembly having a battery, wherein a multi-functional vehicle helmet is able to communicate with at least a second enabled device.

Microelectronic package communication is described using radio interfaces connected through wiring. One example includes a system board, an integrated circuit chip, and a package substrate mounted to the system board to carry the integrated circuit chip, the package substrate having conductive connectors to connect the integrated circuit chip to external components. A radio on the package substrate is coupled to the integrated circuit chip to modulate the data onto a carrier and to transmit the modulated data. A radio on the system board receives the transmitted modulated data and demodulates the received data, and a cable interface is coupled to the system board radio to couple the received demodulated data to a cable.

The embodiments of the invention provide a signal transmission method and apparatus. The method comprises: a first apparatus determines a bandwidth and a quantity of subcarriers of a target channel, wherein the bandwidth and the quantity of the subcarriers of the target channel are determined according to a level and/or a type of terminal equipment using the target channel; and the first apparatus transmits, according to the bandwidth and the quantity of the subcarriers of the target channel, via the target channel, and to a second apparatus, a signal, or receives a signal sent from the terminal device via the target channel, wherein at least one of the first apparatus and the second apparatus is the terminal equipment. The embodiment of the invention can prevent resource wastage.