The invention relates to a circuit for controlling light sources for a luminous garment, such as footwear, jackets, trousers, caps, belts. The circuit comprises an electric power source, such as a battery, a processor, one or more light sources and a switch. The processor and the light sources are powered by the electric power source. The light sources are connected to the processor, which controls their turning on and turning off, for example selectively based on a light program. The switch is connected to both the electric power source and the processor, and can be operated by the user in order to switch the processor on and off. The circuit is advantageously configured so that the electric resistance inside the processor, between the contact with the switch and the contact with the positive pole of the electric power source, is higher than the circuit resistance upstream of the processor itself, i.e. the resistance between the electric power source and the contact of the processor with the switch. In the event that water or condensation cause the circuit to close, even though the switch is in the open position, the current powering the processor is still insufficient to cause it to be switched on. A method for activating light sources in a luminous garment is also described.

Apparatuses and methods for phase interpolating clock signals and for providing duty cycle corrected clock signals are described. An example apparatus includes a clock generator circuit configured to provide first and second clock signals responsive to an input clock signal. A duty phase interpolator circuit may be coupled to the clock generator circuit and configured to provide a first and second duty cycle corrected interpolated clock signals. A duty cycle adjuster circuit may be coupled to the duty phase interpolator circuit and configured to receive the first and second duty cycle corrected interpolated clock signals and provide a duty cycle corrected clock signal responsive thereto. A duty cycle detector may be coupled to the duty cycle adjuster circuit and configured to detect duty cycle error of the duty cycle corrected clock signal and provide the adjustment signals to correct the duty cycle error.

A data communication system has a first data communication circuit for outputting a clock signal to a clock signal line, receiving data input from a data signal line, and outputting data as open drain output to the data signal line, a second data communication circuit for receiving input of a clock signal from the clock signal line, receiving input of data from the data signal line, and outputting data as open drain output to the data signal line, a first pull-up resistor connected between the data signal line and the wiring of a power supply potential, a second pull-up resistor for selectively pulling up the data signal line, and a pull-up control circuit that is connected to the second pull-up resistor, and strengthens pull-up of the data signal line at least in response to a clock signal.

The present disclosure describes embodiments of a write assist circuit. The write assist circuit can include a control circuit and a voltage generator. The control circuit can be configured to receive memory address information associated with a memory write operation for memory cells. The voltage generator can be configured to provide a reference voltage to one or more bitlines coupled to the memory cells. The voltage generator can include two capacitive elements, where during the memory write operation, (i) one of the capacitive elements can be configured to couple the reference voltage to a first negative voltage, and (ii) based on the memory address information, both capacitive elements can be configured to cumulatively couple the reference voltage to a second negative voltage that is lower than the first negative voltage.

A data communication system has a first data communication circuit for outputting a clock signal to a clock signal line, receiving data input from a data signal line, and outputting data as open drain output to the data signal line, a second data communication circuit for receiving input of a clock signal from the clock signal line, receiving input of data from the data signal line, and outputting data as open drain output to the data signal line, a first pull-up resistor connected between the data signal line and the wiring of a power supply potential, a second pull-up resistor for selectively pulling up the data signal line, and a pull-up control circuit that is connected to the second pull-up resistor, and strengthens pull-up of the data signal line at least in response to a clock signal.

A combinational circuit (e.g., multiplexer or demultiplexer) comprises a sub-circuit that comprises first and second current paths from an input of the combinational circuit to an output of the combinational circuit, such that substantially all input current at the input of the combinational circuit is conducted by the sub-circuit via the first and second current paths to the output of the combinational circuit. The first current path comprises a first inductor and a first switch; and the second current path comprises a second inductor and a second switch. The first inductor is part of an output LC transmission line of the sub-circuit; the second inductor is part of an input LC transmission line of the sub-circuit; and the first and second inductors are sized such that parasitic capacitances of the first and second switches are substantially absorbed by the input and output LC transmission lines.

Apparatuses and methods for phase interpolating clock signals and for providing duty cycle corrected clock signals are described. An example apparatus includes a clock generator circuit configured to provide first and second clock signals responsive to an input dock signal. A duty phase interpolator circuit may be coupled to the dock generator circuit and configured to provide a first and second duty cycle corrected interpolated clock signals. A duty cycle adjuster circuit may be coupled to the duty phase interpolator circuit and configured to receive the first and second duty cycle corrected interpolated clock signals and provide a duty cycle corrected dock signal responsive thereto. A duty cycle detector may be coupled to the duty cycle adjuster circuit and configured to detect duty cycle error of the duty cycle corrected clock signal and provide the adjustment signals to correct the duty cycle error.

A transmitter controls the fall time on an open-drain link including multiple components. The transmitter includes an input driver to receive data and transmit the data on the open-drain link, thereby activating the open-drain link. The transmitter also includes a feedback mechanism to keep track of a pad when the open-drain link is activated and to determine when the pad reaches a predetermined amount of a supply voltage. When the pad reaches the predetermined amount of a supply voltage, the feedback mechanism triggers an appropriate main pull-down driver to control the fall time.

Apparatuses and methods for phase interpolating clock signals and for providing duty cycle corrected clock signals are described. An example apparatus includes a clock generator circuit configured to provide first and second clock signals responsive to an input dock signal. A duty phase interpolator circuit may be coupled to the dock generator circuit and configured to provide a first and second duty cycle corrected interpolated clock signals. A duty cycle adjuster circuit may be coupled to the duty phase interpolator circuit and configured to receive the first and second duty cycle corrected interpolated clock signals and provide a duty cycle corrected dock signal responsive thereto. A duty cycle detector may be coupled to the duty cycle adjuster circuit and configured to detect duty cycle error of the duty cycle corrected clock signal and provide the adjustment signals to correct the duty cycle error.

An on-board device installed in a vehicle and is provided with an input circuit including an input end into which an input voltage is entered, and a drive power supply circuit that outputs a drive voltage to the input circuit. The input circuit includes a PNP bipolar transistor, a pull-up circuit, a second pull-up resistance, and a base resistance. The pull-up circuit includes a pull-up power supply, a first pull-up resistance, and a second diode with an anode facing the first pull-up resistance, which are connected in series and are provided between a base of the PNP bipolar transistor and the input end. The second pull-up resistance is provided between the base of the PNP bipolar transistor and the drive power supply circuit. The base resistance is provided between the base of the PNP bipolar transistor and the second pull-up resistance.