A gated tri-state (G3S) inverter includes: first, second and third transistors of a first dopant type (D1 transistors) and first, second and third transistors of a second dopant type (D2 transistors) serially connected between a first reference voltage and second reference voltage, the second dopant type being different than the first dopant type; gate terminals of an alpha one of the noted D1 transistors and an alpha one of the noted D2 transistors being configured to receive an input signal; gate terminals of a beta one of the noted D1 transistors and a beta one of the noted D2 transistors being configured to receive a gating signal; a gate terminal of a gamma one of the noted D2 transistors being configured to receive an enable signal; and a gate terminal of a gamma one of the noted D1 transistors being configured to receive an enable_bar signal.

A semiconductor integrated circuit includes a first signal transmission path and a second signal transmission path in parallel with each other, a first variable delay circuit provided on the first signal transmission path and configured to cause a first signal to be delayed by a first delay amount, a duty adjustment circuit provided on the first signal transmission path in series with the first variable delay circuit, and a second variable delay circuit provided on the second signal transmission path and configured to cause a second signal to be delayed by a second delay amount. The first delay amount is smaller than the second delay amount by a third delay amount corresponding to an amount of delay applied to the first signal by the duty adjustment circuit.

The present disclosure relates to a semiconductor integrated circuit and a signal processing method that can improve measurement accuracy. Pulses subjected to pulse generation and disconnection control by a control circuit are supplied to a pulse distribution circuit and a CP circuit. The pulse distribution circuit divides one pulse into two or more pulses that do not overlap each other, and supplies the pulses to a CBCM circuit. The CBCM circuit is configured by connecting a capacitance element to be measured to the output of a measurement core circuit called a pseudo inverter. The CP circuit inputs, to the gate electrode, pulses that cause a channel of a non-measurement MISFET to change from the accumulation state to the inverted state, and monitors, from the substrate side, a CP current flowing through a trap acting as a recombination center of the gate insulating film and the semiconductor substrate interface. The present disclosure can be applied to, for example, a semiconductor integrated circuit for evaluating the characteristics of the gate insulating film of the MISFET.

In a chip-to-chip signaling system includes at least one signaling link coupled between first and second ICs, the first IC has an interface coupled to the signaling link and timed by a first interface timing signal. The second IC has an interface coupled to the signaling link and timed by a second interface timing signal that is mesochronous with respect to the first interface timing signal. The second IC further has phase adjustment circuitry that adjusts a phase of the second interface timing signal using a digital counter implemented with Josephson-junction circuit elements.

In a chip-to-chip signaling system includes at least one signaling link coupled between first and second ICs, the first IC has an interface coupled to the signaling link and timed by a first interface timing signal. The second IC has an interface coupled to the signaling link and timed by a second interface timing signal that is mesochronous with respect to the first interface timing signal. The second IC further has phase adjustment circuitry that adjusts a phase of the second interface timing signal using a digital counter implemented with Josephson-junction circuit elements.

One embodiment includes a clock distribution system. The system includes at least one resonator spine that propagates a sinusoidal clock signal and at least one resonator rib conductively coupled to the at least one resonator spine and arranged as a standing wave resonator. The system further includes at least one coupling capacitor. Each of the at least one coupling capacitor can interconnect at least one of the at least one resonator rib and a respective circuit to capacitively provide a clock current corresponding to the sinusoidal clock signal to the respective circuit to provide functions for the respective circuit.

Droop monitors spread across a system-on-chip (SoC) monitor for voltage droops in regulated supply voltage supplied to logic circuitry of the SoC. In the event of a voltage droop, a clock signal supplied to the logic circuitry is stretched, to temporarily increase a period of the clock signal. The droop monitors may include a sensing delay line provided voltage at the regulated supply voltage, and a reference delay line supplied with a reference voltage, with operations of the delay lines monitored to determine a voltage droop.

Droop monitors spread across a system-on-chip (SoC) monitor for voltage droops in regulated supply voltage supplied to logic circuitry of the SoC. In the event of a voltage droop, a clock signal supplied to the logic circuitry is stretched, to temporarily increase a period of the clock signal. The droop monitors may include a sensing delay line provided voltage at the regulated supply voltage, and a reference delay line supplied with a reference voltage, with operations of the delay lines monitored to determine a voltage droop.

A circuit for estimating a time difference between a first signal and a second signal includes a first signal line for receiving the first signal; a delay unit configured to receive the second signal and delay the second signal so as to provide a plurality of delayed versions of the second signal, each delayed version being delayed by a different amount of delay to the other delayed versions; a comparison unit configured to compare each of the delayed versions of the second signal with the first signal so as to identify which of the delayed versions of the second signal is the closest temporally matching signal to the first signal; and a difference estimator configured to estimate the time difference between the first and second signals in dependence on the identified delayed version.

Embodiments of the disclosure are drawn to apparatuses and methods for transmission beamforming. A multiphase beam steering transmitter may include a transmitter array of multiple transmitters. A transmitter may include a multiphase logic decoder that directly controls a power amplifier to perform a vector addition of a beam phase and amplitude. A transmitter of the array may include a multiphase clock generator that outputs basis phases with embedded phase modulation data which are output to the multiphase logic decoder. The multiphase clock generator may receive a modulated clock signal. The PA may be a multiphase switched capacitor power amplifier. The multiphase logic decoder may output two phases adjacent to a desired phase as inputs to clocks of the SCPA. The multiphase logic decoder may further output a control signal that determines which cells in the SCPA are activated and when.