An architecture to simplify the circuit implementation of the internal analog-to-digital (A/D) converter in a /spl Delta//spl Sigma/ modulator is proposed. The architecture is based on dividing the A/D conversion into two time steps, which makes the internal quantization feasible with much higher resolution than with conventional solutions. Furthermore, the time steps are interleaved so that the resolution improvement is achieved without sacrificing the speed. It is shown, with a linearized model, that the order of the noise shaping is increased by one with respect to the coarse quantization error made during the first step. For a high oversampling ratio, the coarse quantization error made in the first step is easily suppressed to an insignificant level due to the one order higher noise shaping. Depending on the partitioning of the bits between the conversion steps, the coarse error will dominate below a certain oversampling ratio. However, it is shown that the technique can be extended to more than one order higher noise shaping, making it useful for low oversampling ratios as well.
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