A Novel Highly Stable High-Resolution Oversampled - A/d

Feedforward and multiple-feedback - A/D converters offer high-resolution, but are susceptible to instability in the presence of capacitor tolerances in a corresponding switchedcapacitor (SC) hardware implementation. The hitherto - A/D converters are usually based on, a) complementary signal and noise transfer functions, and/or b) unitcircle noise transfer function zeros. This paper is concerned with the development of a novel - A/D converter having, instead, magnitude-squared or magnitude complementary signal and noise transfer functions. The proposed A/D converter exhibits resolution and dynamic range properties similar to those of the existing feedforward and multiplefeedback A/D converters, but oers increased stability performance in the presence of capacitor tolerances in the SC hardware implementation. In addition, the SC hardware implementation of the resulting A/D converter leads to a capacitance spread which is comparable to that of hitherto - A/D converters