Various embodiments relate to delta-sigma loop filters with input feedforward. A delta-sigma loop filter may include a first integrator and a quantizer having an input coupled to an output of the first integrator. The delta-sigma loop filter may further include a first summing node having an output coupled to an input of the first integrator. Further, the delta-sigma loop filter may include a feedforward path from an input of the delta-sigma loop filter to a first input of the first summing node. The delta-sigma loop filter may also include a first feedback path from an output of the quantizer to a second input of the first summing node.

Various embodiments relate to an analog-to-digital converter (ADC). The ADC may include a first channel including a first delta-sigma loop filter and a second channel including a second delta-sigma loop filter. Each of the first delta-sigma loop filter and the second delta-sigma loop filter may include a first integrator and a quantizer having an input coupled to an output of the first integrator. Each of the first delta-sigma loop filter and the second delta-sigma loop filter may also include a first summing node having an output coupled to an input of the first integrator, and a feedforward path from an input of the delta sigma loop filter to a first input of the first summing node. Further, each of the first delta-sigma loop filter and the second delta-sigma loop filter may include a first feedback path from an output of the quantizer to a second input of the first summing node.

Embodiments of An apparatus and method are disclosed. In an embodiment, an apparatus for performing digital infinite impulse response filtering includes a biquad core that includes five multiplier elements, each multiplier element including, a multiplier, a first delay element in series with and after the multiplier, and a second delay element in series with and after the first delay element, and a multiplexer associated with each of the five multiplier elements, each multiplexer configured to provide one of at least two different coefficients to the multiplier of the corresponding multiplier element.

Embodiments of An apparatus and method are disclosed. In an embodiment, an apparatus for performing digital infinite impulse response filtering includes a biquad core that includes five multiplier elements, each multiplier element including, a multiplier, a first delay element in series with and after the multiplier, and a second delay element in series with and after the first delay element, and a multiplexer associated with each of the five multiplier elements, each multiplexer configured to provide one of at least two different coefficients to the multiplier of the corresponding multiplier element.

Various embodiments relate to delta-sigma loop filters with input feedforward. A delta-sigma loop filter may include a first integrator and a quantizer having an input coupled to an output of the first integrator. The delta-sigma loop filter may further include a first summing node having an output coupled to an input of the first integrator. Further, the delta-sigma loop filter may include a feedforward path from an input of the delta-sigma loop filter to a first input of the first summing node. The delta-sigma loop filter may also include a first feedback path from an output of the quantizer to a second input of the first summing node.

Various embodiments relate to an analog-to-digital converter (ADC). The ADC may include a first channel including a first delta-sigma loop filter and a second channel including a second delta-sigma loop filter. Each of the first delta-sigma loop filter and the second delta-sigma loop filter may include a first integrator and a quantizer having an input coupled to an output of the first integrator. Each of the first delta-sigma loop filter and the second delta-sigma loop filter may also include a first summing node having an output coupled to an input of the first integrator, and a feedforward path from an input of the delta-signal loop filter to a first input of the first summing node. Further, each of the first delta-sigma loop filter and the second delta-sigma loop filter may include a first feedback path from an output of the quantizer to a second input of the first summing node.

A method includes receiving an input digital signal and applying the input digital signal to digital filter processing with a corner frequency to produce a filtered output digital signal. The digital filter processing includes a set of multiplication operations using a set of filter multiplication coefficients. The set of multiplication operations is performed by alternately using a first set of approximate multiplication coefficients and a second set of approximate multiplication coefficients different from the first set of approximate multiplication coefficients. The approximate multiplication coefficients in the first set of approximate multiplication coefficients and the second set of approximate multiplication coefficients approximate multiplication coefficients in the set of filter multiplication coefficients as a function of negative power-of-two values. The alternating of multiplication operations results in digital filter processing with average corner frequency approximating the corner frequency.

In a cascaded integrator comb (CIC) filter, a time-varying gain is added before the last integrating stage transforming its sub optimal boxcar impulse response into an FIR filter of arbitrary length. Make the coefficients sparse and taking them from a set of small integers leads to an efficient hardware implementation that does not compromise any of the essential CIC filter characteristics especially the overflow handling. The proposed sparse CIC structure can improve the worst case stop band attenuation by as much as 10 dB while occupying 77% of the chip area and consuming 30% less power compared to a standard a 5.sup.th order CIC filter, and reducing the overall bit growth of the filter and the amount of high rate operations. Design examples are given illustrating the advantages and flexibility of the proposed structure.

In some embodiments, a multiplier-based programmable filter comprises a pre-scaling circuit, a first multiplier circuit coupled to a first output of the pre-scaling circuit and a second output of the pre-scaling circuit, and a second multiplier circuit coupled to the first output of the pre-scaling circuit and the second output of the pre-scaling circuit. In some embodiments, the multiplier-based programmable filter also comprises a first adder coupled to a first output of the first multiplier circuit and a second output of the first multiplier circuit, a second adder coupled to a first output of the second multiplier circuit and a second output of the second multiplier circuit, first register coupled to an output of the first adder and an input of the second adder, and a second register coupled to an output of the second adder.

In some embodiments, a multiplier-based programmable filter comprises a pre-scaling circuit, a first multiplier circuit coupled to a first output of the pre-scaling circuit and a second output of the pre-scaling circuit, and a second multiplier circuit coupled to the first output of the pre-scaling circuit and the second output of the pre-scaling circuit. In some embodiments, the multiplier-based programmable filter also comprises a first adder coupled to a first output of the first multiplier circuit and a second output of the first multiplier circuit, a second adder coupled to a first output of the second multiplier circuit and a second output of the second multiplier circuit, first register coupled to an output of the first adder and an input of the second adder, and a second register coupled to an output of the second adder.