Methods and systems are described for receiving a reference clock signal and a phase of a local oscillator signal at a dynamically-weighted XOR gate comprising a plurality of logic branches, generating a plurality of weighted segments of a phase-error signal, the plurality of weighted segments including positive weighted segments and negative weighted segments, each weighted segment of the phase-error signal having a respective weight applied by a corresponding logic branch of the plurality of logic branches, generating an aggregate control signal based on an aggregation of the weighted segments of the phase-error signal, and outputting the aggregate control signal as a current-mode output for controlling a local oscillator generating the phase of the local oscillator signal, the local oscillator configured to induce a phase offset into the local oscillator signal in response to the aggregate control signal.

A combinational logic circuit includes input circuitry to receive a first and second input signals that transition between supply voltages of first and second voltage domain, respectively. The input circuitry generates, based on the first and second input signals, a first internal signal that transitions between one of the supply voltages of the first voltage domain and one of the supply voltages of the second voltage domain. Output circuitry within the combinational logic circuit generates an output signal that transitions between the upper and lower supply voltages of the first voltage domain in response to transition of the first internal signal.

An apparatus includes a comparator circuit and a clock generation circuit. The comparator circuit is configured to compare a first input signal with a second input signal during a first comparison phase to obtain a comparison result. Furthermore, an output signal is output, wherein a waveform of the output signal indicates the comparison result. During a subsequent regeneration phase, at least a part of the comparator circuit is reset for a subsequent second comparison phase. The comparator circuit is configured to receive a clock signal, and to change from the first comparison phase to the regeneration phase based on the clock signal. The clock generation circuit is configured to receive the output signal or a signal derived therefrom, and to generate the clock signal based on the waveform of the output signal to control the comparator circuit from the comparison phase to the regeneration phase based on the signal waveform.

Logic gate designs (e.g., NAND, NOR, Inverter) for stacked VTFET designs are provided. In one aspect, a logic gate device is provided. The logic gate device includes: at least one top vertical transport field-effect transistor (VTFET1) sharing a fin with at least one bottom VTFET (VTFET2); a power rail connected to a power contact of the logic gate device; and a ground rail, adjacent to the power rail, connected to a ground contact of the logic gate device. A method of forming a logic gate device is also provided

A self-gating flip-flop circuit includes a flip-flop circuit and a clock circuit. The flip-flop circuit includes a clock input. The clock circuit is coupled to the clock input. The clock circuit includes a latch circuit, a reset circuit, and a gate circuit. The reset circuit is coupled to the latch circuit. The gate circuit is coupled to the latch circuit and the clock input.

A device includes an array including a plurality of bit generating cells arranged in a plurality of rows and columns and a PUF generator. The PUF generator includes a plurality of column multiplexers, each column multiplexer coupled to a plurality of the columns from the array; a plurality of sense amplifiers, each sense amplifier being associated with a respective one of the column multiplexers; and a plurality of de-biasing circuits, each de-biasing circuit associated with a respective column multiplexer and coupled to an output of a respective one of the sense amplifiers. Each de-biasing circuit is operable to provide an output for generating a PUF signature that is dependent on more than one sensed bit from the bit generating cells associated with the columns coupled to the de-biasing circuit's respective column multiplexer, whereby a sensing bias of the sense amplifier to which the de-biasing circuit is coupled is reduced.

According to the present invention there is provided methods and devices for detecting open and/or short circuits in MEMS micro-mirror devices, which use relative comparisons of voltage levels within the MEMS micro-mirror devices for detecting the occurrence of open and/or short circuits.

Disclosed is a logic circuit using three-dimensionally stacked dual-gate thin-film transistors, including a substrate, a first dual-gate thin-film transistor on the substrate, a second dual-gate thin-film transistor on the first dual-gate thin-film transistor, and a third dual-gate thin-film transistor on the second dual-gate thin-film transistor, wherein the first dual-gate thin-film transistor, the second dual-gate thin-film transistor and the third dual-gate thin-film transistor are electrically connected to each other. The logic circuit of the invention is configured such that dual-gate thin-film transistors are three-dimensionally stacked, whereby the advantages of the dual-gate structure and of thin-film transistors can be exhibited together and the degree of integration can be drastically increased, and a logic gate is made in the area of a single transistor, thereby remarkably simplifying wire and circuit designs.

Various circuit techniques for implementing ultra high speed circuits use current-controlled CMOS (C.sup.3MOS) logic fabricated in conventional CMOS process technology. An entire family of logic elements including inverter/buffers, level shifters, NAND, NOR, XOR gates, latches, flip-flops and the like are implemented using C.sup.3MOS techniques. Optimum balance between power consumption and speed for each circuit application is achieve by combining high speed C.sup.3MOS logic with low power conventional CMOS logic. The combined C.sup.3MOS/CMOS logic allows greater integration of circuits such as high speed transceivers used in fiber optic communication systems.

Logic gate designs (e.g., NAND, NOR, Inverter) for stacked VTFET designs are provided. In one aspect, a logic gate device is provided. The logic gate device includes: at least one top vertical transport field-effect transistor (VTFET1) sharing a fin with at least one bottom VTFET (VTFET2); a power rail connected to a power contact of the logic gate device; and a ground rail, adjacent to the power rail, connected to a ground contact of the logic gate device. A method of forming a logic gate device is also provided.