Area and Power consumption are important design metrics in integrated circuit (IC), in particular in those targeted for wearable devices. Σ-Δ Analog to Digital Converter (ADC) are increasing in popularity in those devices thanks to the low bandwidth of a great number of sensors that permits to increase converter performances by the oversampling and noise shaping techniques. One of the most important part of the Σ-Δ ADC is the decimation filter, usually implemented as a Cascaded — Integrator — Comb (CIC). The various CIC architectures, in particular the Recursive and Non recursive — Polyphase ones, are well known in literature. However, filters on-chip performances are strictly related to the effective implementations. The aim of this paper is to evaluate the two architectures, with different values of the characteristic parameters, optimizing the −180 nm CMOS Standard Cell technology — design for a reduced area occupation or power consumption. Results prove that polyphase implementations, differently from theoretical analysis, are generally more power efficient than the recursive one only in a clock gated design, even with a higher area occupation. In addition, an estimation of the power consumption is provided using least squares regression.

Area and power consumption trade-off for Σ-Δ decimation filter in mixed signal wearable IC

PALLA, ALESSANDRO;FANUCCI, LUCA
2016-01-01

Abstract

Area and Power consumption are important design metrics in integrated circuit (IC), in particular in those targeted for wearable devices. Σ-Δ Analog to Digital Converter (ADC) are increasing in popularity in those devices thanks to the low bandwidth of a great number of sensors that permits to increase converter performances by the oversampling and noise shaping techniques. One of the most important part of the Σ-Δ ADC is the decimation filter, usually implemented as a Cascaded — Integrator — Comb (CIC). The various CIC architectures, in particular the Recursive and Non recursive — Polyphase ones, are well known in literature. However, filters on-chip performances are strictly related to the effective implementations. The aim of this paper is to evaluate the two architectures, with different values of the characteristic parameters, optimizing the −180 nm CMOS Standard Cell technology — design for a reduced area occupation or power consumption. Results prove that polyphase implementations, differently from theoretical analysis, are generally more power efficient than the recursive one only in a clock gated design, even with a higher area occupation. In addition, an estimation of the power consumption is provided using least squares regression.
2016
978-1-5090-1095-0
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11568/832783
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