This paper presents a reconfigurable discrete-time audio Sigma-Delta modulator implemented in 0.18-µm CMOS technology. The 600, µm, Ã, 400, µm core area SD modulator is based on a 2, +, 2 MASH architecture, and features several different operating modes in which noise-shaping order, number of output word bits, sampling rate, and bandwidth can be programmed ad hoc. By design, the power consumption is minimized for the selected operating mode. The achieved performance ranges from 99-dB DR with 4th-order noise shaping and full standard audio bandwidth, while consuming 0.97 mW down to 85-dB DR with second order noise shaping over reduced bandwidth for vocal control operation, while consuming 100, µW. The developed device can be used either to read-out different sources (microphones) or to operate in different modes within the same system (i.e. with the same microphone in different scenarios). The trade-off between performance and re-configurability is the key element of this work.
Grassi, M., Conso, F., Rocca, G., Malcovati, P., Baschirotto, A. (2018). Re-configurable Switched Capacitor Sigma-Delta Modulator for MEMS Microphones in Mobiles. In A. Leone, A. Forleo, L. Francioso, S. Capone, P. Siciliano, C. Di Natale (a cura di), 19th AISEM National Conference on Sensors and Microsystems, 2017; Lecce; Italy; 21-23 February 2017 (pp. 9-13). Springer Verlag [10.1007/978-3-319-66802-4_2].
Re-configurable Switched Capacitor Sigma-Delta Modulator for MEMS Microphones in Mobiles
Baschirotto, A
2018
Abstract
This paper presents a reconfigurable discrete-time audio Sigma-Delta modulator implemented in 0.18-µm CMOS technology. The 600, µm, Ã, 400, µm core area SD modulator is based on a 2, +, 2 MASH architecture, and features several different operating modes in which noise-shaping order, number of output word bits, sampling rate, and bandwidth can be programmed ad hoc. By design, the power consumption is minimized for the selected operating mode. The achieved performance ranges from 99-dB DR with 4th-order noise shaping and full standard audio bandwidth, while consuming 0.97 mW down to 85-dB DR with second order noise shaping over reduced bandwidth for vocal control operation, while consuming 100, µW. The developed device can be used either to read-out different sources (microphones) or to operate in different modes within the same system (i.e. with the same microphone in different scenarios). The trade-off between performance and re-configurability is the key element of this work.
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