One embodiment of the present invention relates to a method for transmission a sidelink signal by a terminal in a wireless communication system, and the method comprises: a step of determining a transmission power of a physical sidelink control channel (PSCCH) and a physical sidelink shared channel (PSSCH); and a step of transmitting the PSCCH and the PSSCH with the determined transmission power, wherein the PSCCH and the PSSCH are frequency division multiplexed (FDM) in one subframe and transmitted, and when a modulation and coding scheme (MCS) or a modulation order is equal to or larger than a predetermined value, the power offset value for increasing the transmission power is not applied when determining the PSCCH transmission power. The terminal is included in an autonomous vehicle.

A method of operating a network server, such as a mobile application gateway, connect devices on a cellular or carrier network with individual networks, such as enterprise voice and data networks or residential networks. The effects of the present invention are far reaching in terms of transferring effective call control from the cellular network into the control of the individual network, such as the enterprise, and enabling new business models for the purchase of cellular service from a public cellular carrier by an enterprise.

In some embodiments, a transceiver is configured to wirelessly transfer data between a host computing device and a plurality of peripheral devices over a communication path using a communication data construct sent by the transceiver comprising a plurality of packet structures forming a communication protocol for communicating peripheral device data (HID or audio data) between the host device and the plurality of peripheral devices. Each of the packet structures of the plurality of packet structures can include a single destination address configured to identify which of the plurality of peripheral devices will receive peripheral device data from the host computing device in the present packet structure and which of the plurality of computer peripheral devices will not receive peripheral device data from the host computing device in a present packet structure; and a data field configured to contain peripheral operational data for each of the plurality of peripheral devices.

In some embodiments a transceiver is configured to wirelessly transfer data between a host computing device and one or more peripheral devices over a communication path using a communication data construct comprising a packet structure arranged in a repetitive communication structure. The repetitive communication structure can include a transmit time window within which the host transmits data to the one or more connected peripheral devices and a receive time window within which the host receives data from the one or more connected peripheral devices. A duration of the receive time window is set based on a predetermined communication report rate between the host computing device and the one or more connected peripheral devices. A new peripheral device is added as a connected peripheral device when the new peripheral device transmits a request to the host to be added as a connected peripheral device and the receive time window has time available to add the new peripheral device.

Techniques including controlling coupling and uncoupling of RF ports included in an RF switch matrix including first-side RF ports and second-side RF ports, where each of the first-side RF ports is configured to be selectively coupled to at least one of two or more of the second-side RF ports, identifying one or more of the second-side RF ports as active ports including an active port, causing the RF switch matrix to couple the active port to a signal port included in the first-side RF ports, obtaining at least one of a bit error rate and a signal to noise ratio for a demodulation of an RF stream received via the active port, and causing, in response to at least one of the bit error rate or the signal to noise ratio, the RF switch matrix to couple the signal port to a spare port included in the second-side RF ports.

Aspects of the subject disclosure may include, for example, a repeater device having a first coupler to extract downstream channel signals from first guided electromagnetic waves bound to a transmission medium of a guided wave communication system. An amplifier amplifies the downstream channel signals to generate amplified downstream channel signals. A channel selection filter selects one or more of the amplified downstream channel signals to wirelessly transmit to the at least one client device via an antenna. A second coupler guides the amplified downstream channel signals to the transmission medium of the guided wave communication system to propagate as second guided electromagnetic waves. Other embodiments are disclosed.

A system, server, and method of DTMF detection in a VoIP network.

It is provided a method for adjusting alignment for microwave transmissions from a microwave transmitter to a microwave receiver based on a reinforcement learning, RL, model. The method comprises the steps of: obtaining state space comprising external state space and internal state space, the external state space comprising at least one value of a parameter related to environmental conditions, and the internal state space relates to alignment of the microwave transmitter; determining an action in an action space, the action space comprising actions to adjust alignment of the microwave transmitter; obtaining a measurement of path loss for a transmission from the microwave transmitter to the microwave receiver; determining a reward value based on the path loss, wherein an increase in path loss results in a reduced reward value; and adjusting the RL model based on the obtained state space, the determined action and the determined reward value.

One example of a removable module includes an optical transceiver, optical cables, electrical cables, a power conditioner, and a housing. The optical transceiver converts optical signals received through an optical cable to electrical signals to distribute to a plurality of computing devices through electrical cables and converts electrical signals received from the plurality of computing devices through the electrical cables to optical signals to transmit through the optical cable. The power conditioner receives power from a system with the removable module installed in the system to provide power to the optical transceiver. The housing encloses the optical transceiver and the power conditioner and includes an air intake port and an air exhaust vent. The housing is received by a bay of the system, which provides an interface to the power conditioner and provides air to the air intake port with the removable module installed in the system.

A channel propagation emulator includes a radio peripheral configured to receive input radio frequency (RF) data and modify the input RF data according to channel effects including signal delay, propagation loss and Doppler shift effect to generate an RF output, and a host device operably coupled to the radio peripheral. The RF output represents a modification of the input RF data based on a propagation model. The host device operably coupled to an external controller and is configured to define emulation parameters based on the propagation model. The propagation model is selected at the external controller. The external controller is configured to provide instructions for implementing the Doppler shift effect to include spreading that is multiplicative in frequency.