Provided is a DA converter for outputting an analog signal according to an input digital signal, including a plurality of current output units to be input with the digital signal, which output a current according to the digital signal to a corresponding wiring, a conversion unit provided with a plurality of feedback paths respectively coupled to wirings corresponding to the current output units, and which selects at least one wiring among the wirings corresponding to the current output units and output an analog signal according to a current flowing in the selected wiring, and a first noise reduction unit provided with a plurality of first switches each of which switches whether to electrically connect to at least one wiring among the wirings corresponding to the current output units, and reduces a noise component generated in at least one of the plurality of current output units from the electrically coupled wiring.

In certain examples, methods and semiconductor structures are directed to an apparatus including a photon emitter such as an LED which operates over an emission wavelength range and a photo-voltaic device arranged relative to the photon emitter to provide index-matched optical coupling between the photo-voltaic device and the photon emitter for an emission wavelength range of the photon emitter.

In certain examples, methods and semiconductor structures are directed to an apparatus including a photon emitter such as an LED which operates over an emission wavelength range and a photo-voltaic device arranged relative to the photon emitter to provide index-matched optical coupling between the photo-voltaic device and the photon emitter for an emission wavelength range of the photon emitter.

Programmable components of a quantum processor may be selectively programmed using digital to analog converters (DACs). A DAC with a first stage and a second stage and first and second quantum flux parametron (OFF) loops galvanically coupled to and extending from a respective one of the first stage and the second stage is discussed. The first stage has a first storage loop interrupted by a first Josephson junction and an interface for communicating with an external component. The second stage has a second storage loop interrupted by a second Josephson junction, the second storage loop galvanically coupled to the first storage loop, the first Josephson junction and the second Josephson junction coupled in series to a first control line. A method of loading flux quanta into targeted DAC stages is also discussed.

Programmable components of a quantum processor may be selectively programmed using digital to analog converters (DACs). A DAC with a first stage and a second stage and first and second quantum flux parametron (OFF) loops galvanically coupled to and extending from a respective one of the first stage and the second stage is discussed. The first stage has a first storage loop interrupted by a first Josephson junction and an interface for communicating with an external component. The second stage has a second storage loop interrupted by a second Josephson junction, the second storage loop galvanically coupled to the first storage loop, the first Josephson junction and the second Josephson junction coupled in series to a first control line. A method of loading flux quanta into targeted DAC stages is also discussed.

Enhanced operational amplifier trim circuitry and techniques are presented herein. In one implementation, a circuit includes a reference circuit configured to produce a set of reference voltages, and a digital-to-analog conversion (DAC) circuit. The DAC circuit comprises a plurality of transistor pairs, where each pair among the plurality of transistor pairs is configured to provide portions of adjustment currents for an operational amplifier based at least on the set of reference voltages and sizing among transistors of each pair. The circuit also includes drain switching elements coupled to drain terminals of the transistors of each pair and configured to selectively couple one or more of the portions of the adjustment currents to the operational amplifier in accordance with digital trim codes.

Enhanced operational amplifier trim circuitry and techniques are presented herein. In one implementation, a circuit includes a reference circuit configured to produce a set of reference voltages, and a digital-to-analog conversion (DAC) circuit. The DAC circuit comprises a plurality of transistor pairs, where each pair among the plurality of transistor pairs is configured to provide portions of adjustment currents for an operational amplifier based at least on the set of reference voltages and sizing among transistors of each pair. The circuit also includes drain switching elements coupled to drain terminals of the transistors of each pair and configured to selectively couple one or more of the portions of the adjustment currents to the operational amplifier in accordance with digital trim codes.

A current steering digital-to-analog converter includes a plurality of current cells each including a current source circuit and a current switch circuit to selectively output a current in response to a first input signal corresponding to a digital signal; a dummy current cell including a dummy current source circuit and a dummy current switch circuit to output a current in response to a second input signal; and a current switch bias circuit coupled to the dummy current cell to track a first voltage of an internal node of the dummy current source circuit and configured to generate a first bias voltage applied to the current switch circuit.

Technologies for low jitter and low power ring oscillators with multi-phase signal reassembly are described. A ring oscillator circuit includes a ring oscillator with a set of M delay stages, each stage outputs a phase signal, where M is a positive integer greater than one. The ring oscillator circuit includes a phase selector circuit coupled to the ring oscillator. The phase selector circuit can receive M phase signals from the ring oscillator and generate N phase signals based on the M phase signals, where N is a positive integer less than M.

Technologies for low jitter and low power ring oscillators with multi-phase signal reassembly are described. A ring oscillator circuit includes a ring oscillator with a set of M delay stages, each stage outputs a phase signal, where M is a positive integer greater than one. The ring oscillator circuit includes a phase selector circuit coupled to the ring oscillator. The phase selector circuit can receive M phase signals from the ring oscillator and generate N phase signals based on the M phase signals, where N is a positive integer less than M.