A data network has at least three line branches connected via a common star node to distribute message signals from one of the line branches onto the other line branches, wherein connected to at least one of the line branches is at least one bus-user device is configured to generate in a corresponding transmit mode by a corresponding transmit unit at least one of the message signals, wherein in the corresponding bus-user device, the transmit unit has a current source circuit which, in generating the message signal (16), is configured to inject an electric current into electrical lines of the line branch to which the bus-user device is connected, and via the current source circuit the lines are connected to an internal impedance value of the current source circuit that in transmit mode is constantly greater than 10 times the value of the characteristic impedance, for example greater than 500 Ohms.

A circuit for controlling a switch of a power converter includes a first clock signal generator configured to generate a first clock signal and a switching signal generator configured to generate a switching signal to control the switch of the power converter based on the first clock signal. The circuit further includes error detection circuitry configured to output an error indication and a second clock signal generator configured to generate, in response to the error indication, a second clock signal that comprises an edge of a clock cycle of the second clock signal that corresponds to when the switching signal deactivates the switch of the power converter plus a time delay. The switching signal generator is configured to generate the switching signal to control the switch of the power converter further based on the second clock signal in response to the error indication being output by the error detection circuitry.

Provided is an integrated circuit. The integrated circuit includes a plurality of clock generators configured to respectively generate a plurality of clock signals, a plurality of logic circuits configured to operate in synchronization with the plurality of clock signals, and controller circuitry configured to identify meta-stability information based on frequencies of the plurality of clock signals, and configured to control at least one clock generator so that at least one of the plurality of clock signals is randomly delayed in response to the meta-stability information.

Disclosed is a transmitter which includes a channel driver that includes a pull-up transistor and a pull-down transistor connected between a power node and a ground node and outputs a voltage between the pull-up transistor and the pull-down transistor as a transmit signal, and a pre-driver that controls the pull-up transistor and the pull-down transistor in response to a driving signal and controls the channel driver such that the transmit signal is overshot at a rising edge of the driving signal and the transmit signal is undershot at a falling edge of the driving signal.

An integrated circuit includes a signal output circuit configured to output a timing signal indicating first and second timings of respectively switching first and second switching devices, first and second hold circuits respectively configured to receive first and second voltages corresponding to temperatures of the first and second switching devices, hold the first and second voltages for first and second time periods, and output the received first and second voltages in response to the first and second time periods having elapsed, and first and second control circuits respectively configured to control switching of the first and second switching devices with first and second driving capabilities corresponding to the temperatures of the first and second switching devices, based on the first and second voltages outputted from the first and second hold circuits and first and second driving signals for driving the first and second switching device.

An impedance measurement circuit and an operating method thereof are provided. The impedance measurement circuit includes a current source, a voltage controlled oscillator (VCO), an operation circuit, and a first delay circuit. The current source, electrically connected to a power rail, is able to sink a current from the power rail according to the delayed clock signal. The VCO is configured to generate an oscillation signal according to a power voltage on the power rail. The operation circuit is electrically connected to the VCO and is configured to receive a sampling clock signal and the oscillation signal, sense the power voltage to generate a sampled signal, and accumulate the sampled signal to generate a measurement result. The first delay circuit, electrically connected to the current source and the operation circuit, is able to receive the sampling clock signal and transmit the delayed clock signal to the current source.

Embodiments herein relate to a clock interpolation system. The system may be configured to identify, at a change in logical state of a recovered clock signal, a logical state of a first signal when the first signal is delayed by a delay value. The system may be further configured to identify, at a change in logical state of a second signal, a logical state of the clock signal when the clock signal is delayed by the delay value. Based on the two identifications, the delay value and/or a timing of the clock signal may be adjusted. Other embodiments may be described and/or claimed.

A drive circuit of a voltage-controlled power semiconductor element, including first to fourth switching elements, first and second delay circuits, an overcurrent detection circuit, a slow shutdown detection circuit and a flip-flop. The first switching element turns on upon receiving an off signal. The second switching element is turned on by the first delayed signal generated by the first delay circuit. The third switching element turns on upon receiving a second delayed signal generated by the second delay circuit through the flip-flop. The fourth switching element is turned on by the slow shutdown detection signal generated by the slow shutdown detection circuit. The first to fourth switching elements extract electric charges from the gate terminal of the voltage-controlled power semiconductor element, with first to fourth extracting capabilities, respectively. The first and fourth extracting capabilities are larger than the third extracting capability and smaller than the second extracting capability.

A transmitter circuit applicable to a digital isolator is provided, adapted to receive a data input signal and coupled to an isolation barrier, developing a receiver input signal to a receiver circuit for generating a data output signal. The transmitter circuit generates a transmitter output signal in response to a rising edge and falling edge of the data input signal, and includes a rising and falling converter for outputting a converted data input signal according to the rising edge and falling edge of the data input signal, a delay and logic unit for receiving the converted data input signal and generating a carrier signal, and an AND gate receiving the converted data input signal and the carrier signal, and outputting the transmitter output signal. Since a number of pulses of the carrier signal is limited and definite, the present invention achieves to reduce power consumption and electromagnetic interferences effectively.

Systems, devices, computer-implemented methods, and/or computer program products that facilitate low power, wideband multitone generation. In one example, a multitone generator device can comprise a controller operatively coupled to first and second digital-to-analog converters (DACs). The controller can apply different delays of a sampling signal to the first and second DACs to facilitate sideband suppression of signals output by the first and second DACs. One aspect of such a multitone generator device is that the multitone generator device can facilitate low power, wideband multitone generation.