A method adapts a resonant frequency of a first filter of a closed control loop to a given frequency. The method includes feeding an output signal of a delta sigma modulator of the closed control loop into a frequency adaptation circuit and determining a first noise spectrum of the output signal in a first frequency band and a second noise spectrum of the output signal in a second frequency band. The first frequency band and the second frequency band are arranged symmetrically with respect to the given frequency. The method includes comparing the first noise spectrum with the second noise spectrum, generating an adaptation signal that causes a frequency adaptation of the resonant frequency if the first noise spectrum differs from the second noise spectrum, and outputting the adaptation signal from the frequency adaptation circuit to a control input of the first filter for adapting the resonant frequency.

Provided are, among other things, systems, apparatuses methods and techniques for automatically adjusting the noise-transfer-function of a modulator which is designed to attenuate the level of unwanted noise and/or distortion in a particular frequency band, without similarly attenuating the level of a desired signal in the same frequency band. One such apparatus includes a processing block for generating and injecting an explicit reference signal, and a processing block for detecting the amplitude of that reference signal.

A sigma-delta modulation device includes a detection circuit and a sigma-delta modulator. The detection circuit is configured to detect an input signal to generate a detection signal, and compare the detection signal and a threshold to generate a control signal. The sigma-delta modulator is coupled to the detection circuit and configured to store a plurality of noise transfer functions, select one of the noise transfer functions according to the control signal, and convert the input signal into an output signal according to the noise transfer function.

A wide bandwidth ADC circuit that combines a resistive-input continuous-time sigma-delta ADC circuit with a second ADC circuit having a switched capacitor input. The combination of these two ADC circuits can achieve an easy-to-drive, alias free, wide bandwidth ADC that has excellent DC precision.

A sigma-delta modulation device includes a detection circuit and a sigma-delta modulator. The detection circuit is configured to detect an input signal to generate a detection signal, and compare the detection signal and a threshold to generate a control signal. The sigma-delta modulator is coupled to the detection circuit and configured to store a plurality of noise transfer functions, select one of the noise transfer functions according to the control signal, and convert the input signal into an output signal according to the noise transfer function.

A delta sigma modulator includes two adders, an integrator stage, a reconfigurable local resonator, an analog-to-digital converter (ADC), and a digital-to-analog converter (DAC). A first adder receives an analog input signal at an additive input, and the integrator stage receives an output from the first adder and generates an integrated signal. The reconfigurable local resonator receives the integrated signal and generates a resonator output signal. A second adder receives the resonator output signal, the integrated signal, and the input signal. The ADC receives an output from the second adder and generates a digital output signal which can be provided to other circuits. The DAC receives the digital output signal, and generates and provides a feedback signal to a subtractive input of the first adder. The reconfigurable local resonator acts as a resonator, but reconfigures to act as a low pass filter in response to overload conditions.

A delta sigma modulator includes two adders, an integrator stage, a reconfigurable local resonator, an analog-to-digital converter (ADC), and a digital-to-analog converter (DAC). A first adder receives an analog input signal at an additive input, and the integrator stage receives an output from the first adder and generates an integrated signal. The reconfigurable local resonator receives the integrated signal and generates a resonator output signal. A second adder receives the resonator output signal, the integrated signal, and the input signal. The ADC receives an output from the second adder and generates a digital output signal which can be provided to other circuits. The DAC receives the digital output signal, and generates and provides a feedback signal to a subtractive input of the first adder. The reconfigurable local resonator acts as a resonator, but reconfigures to act as a low pass filter in response to overload conditions.

Provided is a delta-sigma AD converter including a delta-sigma modulating section that outputs a digital signal obtained by performing delta-sigma modulation with an oversampling ratio on an input analog signal; a digital filtering section that filters the digital signal with the oversampling ratio; a control terminal into which an external control signal is input; an output control section that performs control to output an output signal based on the filtered digital signal, according to the external control signal; and a setting section that sets the oversampling ratio based on interval information of the external control signal.

A continuous-time (CT) delta-sigma modulator (DSM) based analog to digital converter (ADC) in a radio receive chain supports a wide range of data rates in a power efficient way in a small die area. The ADC utilizes a 2.sup.nd order loop-filter with a single-amplifier loop-filter topology using a two stage Miller amplifier with a feed forward path and a push-pull output stage. High bandwidth operations utilize a negative-R compensation scheme at the amplifier input. Negative-R assistance is disabled for low data rate applications. With the negative-R assistance disabled, loop-filter resistor values are increased, instead of only the loop filter capacitor values to scale the noise transfer function (NTF), thereby limiting the capacitor area needed and enabling lower power operation. The NTF zero location is programmable allowing the NTF zero to be located near the intermediate frequency for different bandwidths to reduce the DSM quantization noise contribution for narrow-band (low data rate) applications.

Provided is a delta-sigma AD converter including a delta-sigma modulating section that outputs a digital signal obtained by performing delta-sigma modulation with an oversampling ratio on an input analog signal; a digital filtering section that filters the digital signal with the oversampling ratio; a control terminal into which an external control signal is input; an output control section that performs control to output an output signal based on the filtered digital signal, according to the external control signal; and a setting section that sets the oversampling ratio based on interval information of the external control signal.