Abstract
This paper presents a dynamic power reduction technique for incremental $\Delta \Sigma $ (I- $\Delta \Sigma $ ) modulators. The technique makes use of the unequal weighting of the digital reconstruction filter. The underlying idea is that the input signal samples are not equally weighted in the higher order reconstruction filter. Thus, it is possible to increase the non-idealities of the I- $\Delta \Sigma $ modulator during the runtime of a single Nyquist conversion, thereby saving power. This principal idea is verified by an example design, where the input-referred noise of the first integrator is dynamically increased, which allows for improved efficiency. The proposed technique is readily applicable to every state-of-the-art I- $\Delta \Sigma $ modulator. Furthermore, it is shown that this property can also be used to switch a single-bit digital-to-analog converter (DAC) into a multibit DAC during runtime, thereby greatly improving the achievable signal-to-quantization-noise ratio (SQNR) without suffering from the DAC non-linearity. The prototype I- $\Delta \Sigma $ modulator is manufactured in a 180-nm CMOS technology and achieves a dynamic range/SNDR = 91.5/86.6 dB for a sampling rate of 200 kS/s while consuming l.l mW from a 3-V supply, while the dynamic power reduction method accounts for 30% power savings.
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