Architectures for maximum-sequence-length digital delta-sigma modulators

In this paper, we extend the idea developed in some of our earlier works of using output feedback to make the quantization step in a digital delta-sigma modulator (DDSM) appear prime. This maximizes the cycle lengths for constant inputs, spreading the quantization error over the maximum number of frequency terms, and consequently, minimizing the power per tone. We show how this concept can be applied to multibit higher order error-feedback modulators (EFMs). In addition, we show that the idea can be implemented in a class of single-quantizer DDSMs (SQ-DDSM) where STF (z) = z(-L) and NTF (z) = (1 - Z(-1))(L)

High-speed nested cascaded MASH Digital Delta-Sigma Modulator-based divider controller

The MASH Digital Delta-Sigma Modulator (DDSM) based divider controller represents a speed bottleneck in state of the art commercial PLL-based fractional-N frequency synthesizers. As next generation systems require higher phase detector frequencies, there is a need to make ever faster divider controllers. This paper describes a fine-grained nested cascaded MASH DDSM which is significantly faster than state of the art divider controllers, thereby eliminating the current speed bottleneck

Prediction of phase noise and spurs in a nonlinear fractional-N frequency synthesizer

Integer boundary spurs appear in the passband of the loop response of fractional-N phase lock loops and are, therefore, a potentially significant component of the phase noise. In spite of measures guaranteeing spur-free modulator outputs, the interaction of the modulation noise from a divider controller with inevitable loop nonlinearities produces such spurs. This paper presents analytical predictions of the locations and amplitudes of the spurs and accompanying noise floor levels produced by interaction between a divider controller output and a PLL loop with a static nonlinearity. A key finding is that the spur locations and amplitudes can be estimated by using only the knowledge of the structure and pdf of the accumulated modulator noise and the nonlinearity. These predictions also offer new insights into why the spurs appear

A spur-free MASH DDSM with high-order filtered dither

A novel dithered multistage noise shaping (MASH) digital delta-sigma modulator (DDSM) that produces a spur-free output spectrum is presented. The order of the least significant bit (LSB) dither shaping can be increased to that of the modulator, without producing spurious tones. Theoretical results prove that the quantization noise is asymptotically white and uncorrelated with the input; this is corroborated by behavioral simulations. © 2011 IEEE