To effectively suppress an idle tone in a delta-sigma modulator that generates a feedback signal by a digital-to-analog converter. A filter integrates a difference between an input analog signal and a feedback signal, and outputs the integrated difference as an integrated signal. A preceding-stage quantizer quantizes an integrated signal into a digital signal, and outputs the resulting digital signal as a preceding-stage output signal. An adder adds a predetermined dithering signal to a preceding-stage output signal, and outputs the resulting signal as a subsequent-stage input signal. A subsequent-stage quantizer configured to quantize the subsequent-stage input signal into a digital signal of a shorter number of bits than a preceding-stage output signal, and outputs the resulting digital signal as a subsequent-stage output signal. A digital-to-analog converter configured to convert a subsequent-stage output signal into an analog signal, and outputs the resulting analog signal to a filter as a feedback signal.

A radio frequency system. In some embodiments, the system includes a one-bit receiver, and the one-bit receiver includes a digital pseudo random noise generator, a one-bit digital to analog converter, a power combiner, a one-bit analog to digital converter, and a digital subtraction circuit. The digital pseudo random noise generator produces a signal added to the received signal before analog to digital conversion. After analog to digital conversion, a delayed version of the dither is subtracted from the digital signal.

To effectively suppress an idle tone in a delta-sigma modulator that generates a feedback signal by a digital-to-analog converter. A filter integrates a difference between an input analog signal and a feedback signal, and outputs the integrated difference as an integrated signal. A preceding-stage quantizer quantizes an integrated signal into a digital signal, and outputs the resulting digital signal as a preceding-stage output signal. An adder adds a predetermined dithering signal to a preceding-stage output signal, and outputs the resulting signal as a subsequent-stage input signal. A subsequent-stage quantizer configured to quantize the subsequent-stage input signal into a digital signal of a shorter number of bits than a preceding-stage output signal, and outputs the resulting digital signal as a subsequent-stage output signal. A digital-to-analog converter configured to convert a subsequent-stage output signal into an analog signal, and outputs the resulting analog signal to a filter as a feedback signal.

A system and method of converting an analog input signal to a linearized digital representation of the analog input signal. A measure of the analog input signal is compared to a threshold associated with a maximum dynamic range of a quantizer. A maximum amplitude of a random, analog dither signal is dynamically varied for perturbing quantization of the analog input signal in response to the comparison. The dynamically varied dither signal and the analog input signal are combined to obtain a dithered input signal. The quantizer converts the dithered input signal into the linearized digital representation of the analog input signal.

A digital signal generation assumes that a base frequency (the frequency with which the primitive phase angles are specified relative to) is equal to the carrier frequency for all relevant times. But this causes errors in the digital signals output to each array element transducer. Thus, it is necessary for the development of a signal generation system that is capable of producing a digital signal using the free selection of amplitude and phase. This is used to produce a substantially error-free signal that preserves the amplitude and phase relative to a constant base frequency while allowing the carrier frequency to vary.

An analog-to-digital converter circuit module utilizing dither to reduce multiplicative noise. A dither generation circuit generates a noise-shaped analog dither signal having lower amplitudes at frequencies below a cutoff frequency than at frequencies above the cutoff frequency. The noise-shaped analog dither signal is added to the input analog signal to be converted and the summed signal applied to an analog-to-digital converter The dither generation circuit may be implemented as an analog dither generator followed by an analog high-pass filter. The dither generation circuit may alternatively be implemented digitally, for example with a digital noise-shaping filter applying a high-pass digital filter to a pseudo-random binary sequence. The digital dither generation circuit may alternatively be implemented by one or more 1-bit sigma-delta modulators, each generating a bit of a digital dither sequence that is converted to analog.

A digital signal generation assumes that a base frequency (the frequency with which the primitive phase angles are specified relative to) is equal to the carrier frequency for all relevant times. But this causes errors in the digital signals output to each array element transducer. Thus, it is necessary for the development of a signal generation system that is capable of producing a digital signal using the free selection of amplitude and phase. This is used to produce a substantially error-free signal that preserves the amplitude and phase relative to a constant base frequency while allowing the carrier frequency to vary.