High-Order Multibit Modulators and Pseudo Data-Weighted-Averaging in Low-Oversampling>tex<$Delta Sigma$>/tex<ADCs for Broad-Band Applications

Abstract

High-speed high-resolution /spl Delta//spl Sigma/ analog-to-digital converters (ADCs) for broad-band communication applications must be designed at a low oversampling ratio (OSR). However, lowering the OSR limits the efficiency of a /spl Delta//spl Sigma/ ADC in achieving a high-resolution A/D conversion. This paper presents several techniques that enable the OSR reduction in /spl Delta//spl Sigma/ ADCs without compromising the resolution. 1) Noise transfer function (NTF). In this paper, a single-stage multibit /spl Delta//spl Sigma/ modulator with a high-order finite-impulse-response NTF is proposed to achieve high signal-to-quantization-noise ratios at low OSRs. Its key features include: decreased circuit complexity, improved robustness to modulator coefficient variations, and reduced sensitivity to integrator nonlinearities. Its performance is validated through behavioral simulations and compared to traditional /spl Delta//spl Sigma/ modulator structures. 2) Signal transfer function (STF). This paper describes how the STF of a /spl Delta//spl Sigma/ modulator can be designed, independently of the NTF, in order to significantly reduce the harmonic distortion due to opamp nonidealities and to help lower the power dissipation. 3) Dynamic element matching (DEM) is also presented. Data weighted averaging (DWA) has prevailed as the most practical DEM technique to linearize the internal digital-to-analog converter (DAC) of a multibit /spl Delta//spl Sigma/ modulator, especially when the number of DAC elements is large. However, the occurrence of in-band signal-dependent tones, when using DWA at a low OSR, degrades the spurious-free dynamic range. This paper proposes a simple technique, called pseudo DWA, to solve the DWA tone problem without sacrificing the signal-to-noise ratio. Its implementation adds no extra delay in the /spl Delta//spl Sigma/ feedback loop and requires only minimal additional digital hardware. Existing schemes for DWA tone reduction are also compared.