Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

Abstract: A system includes a first transceiver and a controller circuit. The first transceiver is configured to transmit first radio frequency (RF) signals. The first transceiver is further configured to output the first RF signals at a first transmission level corresponding to a first transmission range. The controller circuit is communicatively coupled with the first transceiver. The controller circuit is configured to attenuate the first RF signals to transfer the first RF signals at a second transmission level lower than the first transmission level. The second transmission level corresponds to a shorter transmission range than the first transmission range. The controller circuit detects a presence of at least one second transceiver within the shorter transmission range using the first RF signals transmitted at the second transmission level.

Abstract: Examples are disclosed that relate to electronically functional yarns. One example provides an electronically functional yarn comprising a core, a sheath at least partially surrounding the core, and an electronic circuit formed on the core. The circuit includes three or more control lines and more than three diode-containing circuit elements controllable by the three or more control lines, each circuit element being controllable via a corresponding set of two of the three or more control lines.

Abstract: An outdoor satellite receiving unit (ODU) receives several independent satellite signals, selects two signals with a switch matrix, downconverts the two signals to a bandstacked signal with a high and a low band signal, and outputs the bandstacked signal on the same cable to receiver units. Several satellite signals can be selected in groups of two or more and output to independent receiver units. Signal selecting is performed at the received radio frequency (RF) and bandstacking is performed with a single downconversion step to an intermediate frequency (IF). Channel stacking on the same cable of more than two channels from several satellites can be achieved by using frequency agile downconverters and bandpass filters prior to combining at the IF output. A slow transitioning switch minimizes signal disturbances when switching and maintains input impedance at a constant value.

Abstract: Systems and methods for improvement in bus communications with daisy-chained connected devices are described herein. In some embodiments, a bus communication system comprises a master chain controller, a first peripheral device, and a second peripheral device. A first communication bus couples a master interface port of the master chain controller to a slave interface port of the first peripheral device, and a second communication bus couples a master interface port of the first peripheral device to a slave interface port of the second peripheral device. The first communication device is configured to receive a communication packet via the first communication bus and to send a copy of the communication packet to the second peripheral device during transmission of the communication packet to the first peripheral device. The first communication device is also configured to send an idle state signal to the master chain controller.

Abstract: A network communication device, such as an electricity meter, is configured to communicate with devices on a circuit internal to a site via power line communication (PLC), even when electricity service to the site is disconnected. The network communication device is configured to monitor one or more circuits internal to the site and to receive power line communications from the device(s) coupled to the circuit internal to the site when the site is disconnected from electricity service. A PLC module of the network communication device may include a switch-based or capacitor-based monitor that maintains a PLC coupler electrically connected with the circuit internal to the site even when electricity service to the site is disconnected.

Abstract: An outdoor satellite receiving unit (ODU) receives several independent satellite signals, selects two signals with a switch matrix, downconverts the two signals to a bandstacked signal with a high and a low band signal, and outputs the bandstacked signal on the same cable to receiver units. Several satellite signals can be selected in groups of two or more and output to independent receiver units. Signal selecting is performed at the received radio frequency (RF) and bandstacking is performed with a single downconversion step to an intermediate frequency (IF). Channel stacking on the same cable of more than two channels from several satellites can be achieved by using frequency agile downconverters and bandpass filters prior to combining at the IF output. A slow transitioning switch minimizes signal disturbances when switching and maintains input impedance at a constant value.

Abstract: Systems and methods are described herein for determining the location of a transmitter by jointly and collectively processing the full sampled signal data from a plurality of receivers to form a single solution.

Abstract: A passive transponder includes an antenna, an antenna oscillator circuit and a data source. The antenna oscillator circuit is configured to operate at a first resonant frequency or at a second resonant frequency, depending on reception of energy at the transponder or on a data transmission from/to the data source.

Abstract: An identification method and identification device are presented employing radio frequency and acoustic wave communication modes. The identification method includes: receiving at an acoustic wave and radio frequency identification device an acoustic wave signal of a first frequency and a radio frequency signal of a second frequency, where the acoustic wave signal and the radio frequency signal are received from an acoustic wave and radio frequency identification reader, and the first frequency and the second frequency are different frequencies; and responding to the receiving by transmitting at least one of an acoustic wave identification (AWID) or a radio frequency identification (RFID) from the acoustic wave and radio frequency identification device.

Abstract: A receiver circuit includes an analog front-end circuit, a first adaptation circuit, and a second adaptation circuit. A method operates the receiver circuit. The analog front-end circuit is configured to resolve an output signal from an input signal as a function of adjustable parameters. The first adaptation circuit is coupled to the analog front-end circuit and is configured to determine values of the adjustable parameters responsive to the output signal. The second adaptation circuit is coupled to the analog front-end circuit and to the first adaptation circuit. The second adaptation circuit is configured to adjust the values of the adjustable parameters responsive to one or more operating conditions of the receiver circuit. These operating conditions include a temperature and/or a power supply voltage of the receiver circuit.

Abstract: Device (D) for communicating between a mobile element and a fixed element, includes: an electromagnetic field-based reader (L) including a transmitter with a transmitting antenna and a receiver with a first antenna placed in a housing (1), and a beacon (B) including a receiver able to receive a signal originating from the transmitter of the reader (L) so as to provide energy to a transmitter able to dispatch a signal received by the receiver of the reader (L), the receiver of the reader (L) including at least one second antenna and signal comparison elements able to compare the signal received by the first antenna of the receiver with the signal received by the second antenna so as to determine the moment at which the reader (L) passes vertically in line with the beacon (B).

Abstract: An exemplary amplitude shift keying (ASM) demodulator and a radio frequency identification (RFID) system using the same are provided. The ASM demodulator is adapted to demodulate an alternating current input signal and generate a demodulated envelope signal. The ASM demodulator includes a signal input terminal group, an input rectifier circuit, a current mirror circuit electrically coupled to the input rectifier circuit, an output stage electrically coupled to the current mirror circuit, and a low pass filter electrically coupled to the output stage. The input rectifier circuit is electrically coupled to the signal input terminal group and adapted to perform a rectifying operation applied to the alternating current input signal. The input rectifier circuit includes a plurality of electrically coupled transistors and a gate electrode of each of the transistors is unconnected with a source electrode and a drain electrode itself.

Abstract: The invention relates to the control, for example the creation or modification of a lighting scene with a lighting system, and the invention particularly relates to a more easily and user oriented controlling of the creation and modification of the lighting scene.