A semiconductor chip includes a first wireless communication circuit, a local oscillator (LO) buffer, and an auxiliary path. The first wireless communication circuit has a signal path, wherein the signal path has a mixer input port and a signal node distinct from the mixer input port. The auxiliary path is used to electrically connect the LO buffer to the signal node of the signal path. The LO buffer is reused for a transmit (TX) function through the auxiliary path.

A semiconductor chip includes a first wireless communication circuit, a local oscillator (LO) buffer, and an auxiliary path. The first wireless communication circuit has a signal path, wherein the signal path has a mixer input port and a signal node distinct from the mixer input port. The auxiliary path is used to electrically connect the LO buffer to the signal node of the signal path. The LO buffer is reused for a transmit (TX) function through the auxiliary path.

The present disclosure describes techniques and systems for wireless communications between a base station [120] and a user equipment [110] using an enhanced radio-resource control idle mode. The described techniques and systems enable a user equipment [110] to receive a radio-resource control release message [410] that includes a cell radio-network temporary-identifier and, in response, enter [415] the enhanced radio-resource control idle mode. While in the enhanced radio-resource control idle mode, the user equipment [110] may receive a message [420] in accordance with the cell radio-network temporary-identifier and present the received message.

This disclosure describes techniques that enable a Radio Frequency (RF) signal controller and optional digital signal translator to use the existing telecommunication infrastructure of a business or residential establishment to deliver wireless communication services to the business or residential establishment. The data signal controller may transceive a first data signal via a first signal interface, determine if/how to process the first data signal to generate a second data signal that is suitable to be transported into the establishment via legacy telecommunications infrastructure

This disclosure describes techniques that enable a Radio Frequency (RF) signal controller and optional digital signal translator to use the existing telecommunication infrastructure of a business or residential establishment to deliver wireless communication services to the business or residential establishment. The data signal controller may transceive a first data signal via a first signal interface, determine if/how to process the first data signal to generate a second data signal that is suitable to be transported into the establishment via legacy telecommunications infrastructure

The present invention teaches a solenoid-valve actuator that is battery-powered and communicates remotely and wirelessly (e.g., via LoRaWAN) to a gateway that communicates with the internet, thereby enabling a user to remotely control fluid flow through a solenoid valve. The end device interfaces to a range of latching solenoid operated valves, e.g., for the control of water flow in irrigation systems.

The present invention teaches a solenoid-valve actuator that is battery-powered and communicates remotely and wirelessly (e.g., via LoRaWAN) to a gateway that communicates with the internet, thereby enabling a user to remotely control fluid flow through a solenoid valve. The end device interfaces to a range of latching solenoid operated valves, e.g., for the control of water flow in irrigation systems.

This disclosure describes techniques that enable a Radio Frequency (RF) signal controller and optional digital signal translator to use the existing telecommunication infrastructure of a business or residential establishment to deliver wireless communication services to the business or residential establishment. The data signal controller may transceive a first data signal via a first signal interface, determine if/how to process the first data signal to generate a second data signal that is suitable to be transported into the establishment via legacy telecommunications infrastructure.

This disclosure describes techniques that enable a Radio Frequency (RF) signal controller and optional digital signal translator to use the existing telecommunication infrastructure of a business or residential establishment to deliver wireless communication services to the business or residential establishment. The data signal controller may transceive a first data signal via a first signal interface, determine if/how to process the first data signal to generate a second data signal that is suitable to be transported into the establishment via legacy telecommunications infrastructure.

A wireless communication device includes a structural device interface (e.g., a USB interface) for connecting to a computing device and a wireless interface for making a wireless connection to a mobile device. The wireless communication device activates after being connected to the computing device and automatically executes a software application stored in memory of the wireless communication device. Subsequent to being connected to the computing device and executing the software application, the wireless communication device is configured to wirelessly discover the mobile device and wirelessly receive data from the mobile device over a wireless channel, for rendering the wirelessly received data at the computing device.