An ADC circuit (50) is disclosed. It comprises a global input configured to receive an input voltage (V.sub.in) and a plurality of converter circuits (105.sub.1-105.sub.N). Each converter circuit (105.sub.j) comprises a comparator circuit (70.sub.j) having a first input connected to the global input, a second input, and an output configured to output a one-bit output signal of the comparator circuit (70.sub.j). Furthermore, each converter circuit (105.sub.j) comprises a one-bit current-output DAC (110.sub.j) having an input directly controlled from the output of the comparator circuit (70.sub.j) and an output connected to the second input of the comparator circuit (70.sub.j). The second inputs of all comparator circuits are interconnected. The ADC circuit (50) further comprises a digital output circuit (130) configured to generate an output signal z[n] of the ADC circuit (50) in response to the one-bit output signals of the comparator circuits (70.sub.j).

A hybrid delta modulator that can be used as a variable threshold neuron in a neural network is described. The hybrid delta modulator exhibits a memory of the prior state of the modulator, similar to a delta modulator, and receives a sum-of-products signal from a weighting circuit and generates a quantized output stream that represents the sum-of-products signal, potentially including an activation function and offset. With appropriately selected components, the hybrid delta modulator separates the integral function of the feedback from the gain function. Further, the gain can be selected, and the characteristic of the output pattern can be tailored to include an arbitrary combination of the input and the rate of change of the input. The use of a hybrid delta modulator of the present approach provides a simpler solution and better performance than many prior art neurons.

A hybrid delta modulator that can be used as a variable threshold neuron in a neural network is described. The hybrid delta modulator exhibits a memory of the prior state of the modulator, similar to a delta modulator, and receives a sum-of-products signal from a weighting circuit and generates a quantized output stream that represents the sum-of-products signal, potentially including an activation function and offset. With appropriately selected components, the hybrid delta modulator separates the integral function of the feedback from the gain function. Further, the gain can be selected, and the characteristic of the output pattern can be tailored to include an arbitrary combination of the input and the rate of change of the input. The use of a hybrid delta modulator of the present approach provides a simpler solution and better performance than many prior art neurons.

A delta-sigma modulation circuit has a sampling period and, in operation, generates a delta-sigma modulated signal based on the analog input signal. The delta-sigma modulation circuit includes: a first integrator; an analog-to-digital converter; a feedback-loop coupled between an input of the first integrator and the output interface; a second integrator coupled between the first integrator and the analog-to-digital converter. The delta-sigma modulation circuit has loop-delay compensation circuitry having a plurality of switches. The loop delay compensation circuitry, in operation, controls the plurality of switches based on a time interval of a duration of half the sampling period and generates a loop-delay compensation signal.

A delta-sigma modulation circuit has a sampling period and, in operation, generates a delta-sigma modulated signal based on the analog input signal. The delta-sigma modulation circuit includes: a first integrator; an analog-to-digital converter; a feedback-loop coupled between an input of the first integrator and the output interface; a second integrator coupled between the first integrator and the analog-to-digital converter. The delta-sigma modulation circuit has loop-delay compensation circuitry having a plurality of switches. The loop delay compensation circuitry, in operation, controls the plurality of switches based on a time interval of a duration of half the sampling period and generates a loop-delay compensation signal.

An oversampling filter oversamples a digital audio signal. A ΔΣ modulator delta-sigma modulates a signal output from the oversampling filter. A D/A converter converts a signal output from the ΔΣ modulator into an analog audio signal. The oversampling filter includes a processor configured to run firmware and a computational algorithm is configurable based on the firmware.

An oversampling filter oversamples a digital audio signal. A ΔΣ modulator delta-sigma modulates a signal output from the oversampling filter. A D/A converter converts a signal output from the ΔΣ modulator into an analog audio signal. The oversampling filter includes a processor configured to run firmware and a computational algorithm is configurable based on the firmware.

The purpose of the present invention is to provide a high-power-efficiency and low-design-cost transmission device by implementing, with a constant clock, delta-sigma modulation maintaining a zero current switching property in an amplifier. This delta-sigma modulator comprises: a pulse phase signal generation unit for generating a pulse phase signal from a phase signal; a delta-sigma modulation unit for generating a pulse amplitude signal obtained by delta-sigma modulating an amplitude signal with a constant clock; a phase sorting unit for outputting a control signal on the basis of the phase signal; a delay switching unit for delaying the pulse amplitude signal on the basis of the control signal; and a mixing unit for outputting a pulse string obtained by multiplying together the delayed pulse amplitude signal and the pulse phase signal.

The purpose of the present invention is to provide a high-power-efficiency and low-design-cost transmission device by implementing, with a constant clock, delta-sigma modulation maintaining a zero current switching property in an amplifier. This delta-sigma modulator comprises: a pulse phase signal generation unit for generating a pulse phase signal from a phase signal; a delta-sigma modulation unit for generating a pulse amplitude signal obtained by delta-sigma modulating an amplitude signal with a constant clock; a phase sorting unit for outputting a control signal on the basis of the phase signal; a delay switching unit for delaying the pulse amplitude signal on the basis of the control signal; and a mixing unit for outputting a pulse string obtained by multiplying together the delayed pulse amplitude signal and the pulse phase signal.

Superconductor analog-to-digital converters (ADC) offer high sensitivity and large dynamic range. One approach to increasing the dynamic range further is with a subranging architecture, whereby the output of a coarse ADC is converted back to analog and subtracted from the input signal, and the residue signal fed to a fine ADC for generation of additional significant bits. This also requires a high-gain broadband linear amplifier, which is not generally available within superconductor technology. In a preferred embodiment, a distributed digital fluxon amplifier is presented, which also integrates the functions of integration, filtering, and flux subtraction. A subranging ADC design provides two ADCs connected with the fluxon amplifier and subtractor circuitry that would provide a dynamic range extension by about 30-35 dB.