Apparatus and method for a quantum readout instruction. For example, one embodiment of an apparatus comprises: quantum instruction processing circuitry to process a quantum readout instruction to read states of one or more qubits of a quantum processor, the quantum readout instruction comprising instruction fields including a first one or more fields to identify a first target qubit and a second one or more fields to indicate signal processing parameters; and quantum signal processing circuitry coupled to the quantum instruction processing circuitry, the quantum signal processing circuitry to be configured based on the signal processing parameters and to perform a measurement of the first target qubit responsive to the quantum readout instruction.

This application describes a variety of approaches for generating high voltage sinusoidal signals whose output voltage can be adjusted rapidly, without introducing high-frequency artifacts on the output. When these approaches are used, stronger electric fields can be applied to the tumor for a higher percentage of time, which can increase the efficacy of TTFields therapy. In some embodiments, this is accomplished by preventing adjustments to a DC power source during times when the output of that DC power source is powering the output signal. In some embodiments, this is accomplished by synchronizing the operation of an AC voltage generator and an electronic switch that is connected to the output of the AC voltage generator.

Provided are, among other things, systems, apparatuses methods and techniques for generating discrete-time sinusoidal sequences. One such apparatus includes a plurality of parallel processing branches, with each of the parallel processing branches operating at a subsampled rate and utilizing a recursive filter to generate sub-rate samples which represent a different subsampling phase of a complete signal that is output by the apparatus.

One or more examples relate to an apparatus includes an error detector, an oscillator, an analog proportional path, and a digital integral path. The oscillator includes an analog proportional input, a digital integral input, and an analog integral input. The analog proportional path to provide a control signal for the analog proportional input of the oscillator. The digital integral path to provide a control for the digital integral input and the analog integral input of the oscillator. A first signal path of an interface includes a direct coupling between the digital phase detector and integrator and the digital integral input of the oscillator. A second signal path of the interface includes a digital-to-analog converter (DAC) with a filtered delta-sigma modulator (DSM) input between the digital phase detector and integrator and the analog integral input of the oscillator.

A signal generator includes a processing unit. The signal generator is configured to generate at least one periodic output signal. The output signal comprises a triangular-waveform signal. A frequency and an amplitude of the output signal are adjustable. The signal generator is configured to receive an input parameter. The input parameter comprises at least one piece of information about a setpoint amplitude and a setpoint frequency of the output signal. The processing unit is configured to determine a signal direction of the output signal. The processing unit is configured to determine a step size. The processing unit is configured to apply the step size to an actual amplitude based on the signal direction for a number of clock cycles. The number of clock cycles is dependent on the setpoint frequency of the output signal.

The present invention provides a frequency synthesizer that is switchable at a high speed and includes a few unnecessary frequency components in an output frequency signal. In a frequency synthesizer 1, a DDS 2 operates based on a clock signal to generate a reference frequency signal with a predetermined reference frequency, and clock signal supply units 41 and 42 switch the clock signals that have different clock frequencies to supply to the DDS 2. When the clock signals are switched to operate the DDS 2, the storage unit 12 stores a combination of a clock frequency f.sub.clk, a reference frequency f.sub.c, and a dividing number N in association with an output frequency f.sub.VCO of the frequency synthesizer 1 such that a spurious frequency does not exist within a predetermined frequency range and a dividing number of a variable frequency divider 302 disposed on a PLL circuit 3 is minimum. Setting units 11 and 24 read setting items stored in the storage unit 12 to set respective units.

Systems and methods for digital synthesis of an output signal using a frequency generated from a resonator and computing amplitude values that take into account temperature variations and resonant frequency variations resulting from manufacturing variability are described. A direct frequency synthesizer architecture is leveraged on a high Q resonator, such as a film bulk acoustic resonator (FBAR), a spectral multiband resonator (SMR), and a contour mode resonator (CMR) and is used to generate pristine signals.

A signal generating electric circuit, a signal generating method, a digit-to-time converting electric circuit and a digit-to-time converting method. The signal generating electric circuit includes: a first generating electric circuit configured for, based on a first frequency control word and a reference time unit, generating a periodic first output signal; and a second generating electric circuit configured for, based on a second frequency control word and the reference time unit, generating a periodic second output signal. The first frequency control word includes a first integer part and a first fractional part, the second frequency control word includes a second integer part and a second fractional part, the first integer part is equal to the second integer part, the first fractional part is not zero, the second fractional part is zero, and a period of the first output signal and a period of the second output signal are not equal.

Methods and digital circuits providing frequency correction to frequency synthesizers are disclosed. An FLL digital circuit is provided that is configured to handle a reference frequency that is dynamic and ranges over a multi-decade range of frequencies. The FLL circuit includes a digital frequency iteration engine that allows for detection of disappearance of a reference frequency. When the digital frequency iteration engine detects that the reference frequency signal is not available, the oscillator generated frequency is not corrected, and the last value of the oscillator generated frequency is held until the reference frequency signal becomes available again. This FLL circuit is also preceded by a low-pass filter which is dynamically tuned to the frequency to which the FLL locks, eliminating harmonic components in the original signal which might otherwise cause errors in frequency estimation.

An agile frequency synthesizer with dynamic phase and pulse-width control is disclosed. In one aspect, the frequency synthesizer includes a count circuit configured to modify a stored count value by an adjustment value. The frequency synthesizer also includes an output clock generator configured to generate an output clock signal having rising and falling edges that are based at least in part on the stored count value satisfying a count threshold. The count circuit is further configured to alter at least one of the period or phase of the output clock signal based at least in part on modifying an adjustment rate of the count circuit.