An interface circuit includes: a plurality of signal transmitter circuits each receiving an input signal and outputting an output signal responsive to a first power supply voltage based on the input signal; an operation control circuit controlling operation/suspension of the signal transmitter circuits; and an amplitude control circuit exerting control so that the first power supply voltage be greater with increase in the number of operating circuits among the signal transmitter circuits and thereby the amplitude of the output signals of the signal transmitter circuits become greater.

An interface circuit includes: a plurality of signal transmitter circuits each receiving an input signal and outputting an output signal responsive to a first power supply voltage based on the input signal; an operation control circuit controlling operation/suspension of the signal transmitter circuits; and an amplitude control circuit exerting control so that the first power supply voltage be greater with increase in the number of operating circuits among the signal transmitter circuits and thereby the amplitude of the output signals of the signal transmitter circuits become greater.

Techniques and apparatus for reducing low frequency power supply spurs in clock signals in a clock distribution network. One example circuit for clock distribution generally includes a plurality of logic inverters coupled in series and configured to drive a clock signal and a current-starved inverter coupled in parallel (or in series) with a logic inverter in the plurality of logic inverters.

Techniques and apparatus for reducing low frequency power supply spurs in clock signals in a clock distribution network. One example circuit for clock distribution generally includes a plurality of logic inverters coupled in series and configured to drive a clock signal and a current-starved inverter coupled in parallel (or in series) with a logic inverter in the plurality of logic inverters.

A control circuit including a quadrature encoder circuit, a counter circuit, and a cutoff circuit is provided. The quadrature encoder circuit generates a first edge signal and a first direction signal according to a first external signal and a second external signal. The counter circuit performs a counting operation according to the first edge signal and the first direction signal. In response to the timer signal being enabled, the cutoff circuit prevents the first edge signal and the first direction signal from entering the counter circuit and provides a second edge signal and a second direction signal to the counter circuit so that the counter circuit performs the counting operation according to the second edge signal and the second direction signal.

A control circuit including a quadrature encoder circuit, a counter circuit, and a cutoff circuit is provided. The quadrature encoder circuit generates a first edge signal and a first direction signal according to a first external signal and a second external signal. The counter circuit performs a counting operation according to the first edge signal and the first direction signal. In response to the timer signal being enabled, the cutoff circuit prevents the first edge signal and the first direction signal from entering the counter circuit and provides a second edge signal and a second direction signal to the counter circuit so that the counter circuit performs the counting operation according to the second edge signal and the second direction signal.

Systems and techniques for applying voltage biases to gates of driver circuitry of an integrated circuit (IC) based on a detected bus voltage, IC supply voltage, or both are used to mitigate Electrical Over-Stress (EOS) issues in components of the driver circuitry caused, for instance, by high bus voltages in serial communication systems relative to maximum operating voltages of those components. A driver bias generator selectively applies bias voltages at gates of transistors of a stacked driver structure of an IC to prevent the voltage drop across any given transistor of the stacked driver structure from exceeding a predetermined threshold associated with the maximum operating voltage range of the transistors.

Systems and techniques for applying voltage biases to gates of driver circuitry of an integrated circuit (IC) based on a detected bus voltage, IC supply voltage, or both are used to mitigate Electrical Over-Stress (EOS) issues in components of the driver circuitry caused, for instance, by high bus voltages in serial communication systems relative to maximum operating voltages of those components. A driver bias generator selectively applies bias voltages at gates of transistors of a stacked driver structure of an IC to prevent the voltage drop across any given transistor of the stacked driver structure from exceeding a predetermined threshold associated with the maximum operating voltage range of the transistors.

A semiconductor device, able to be selectively configured to perform one or more user defined logic functions, includes a semiconductor die and a selectable power regulator. The semiconductor die, in one aspect, includes a first region and a second region. The first region is operatable to perform a first set of logic functions based on a first power domain having a first voltage. The second region is configured to perform a second set of logic functions based on a second power domain having a second voltage. The selectable power regulator, in one embodiment, provides the second voltage for facilitating the second power domain in the second region of the semiconductor die in response to at least one enabling input from the first region of the semiconductor die.

A semiconductor device, able to be selectively configured to perform one or more user defined logic functions, includes a semiconductor die and a selectable power regulator. The semiconductor die, in one aspect, includes a first region and a second region. The first region is operatable to perform a first set of logic functions based on a first power domain having a first voltage. The second region is configured to perform a second set of logic functions based on a second power domain having a second voltage. The selectable power regulator, in one embodiment, provides the second voltage for facilitating the second power domain in the second region of the semiconductor die in response to at least one enabling input from the first region of the semiconductor die.