Title :
Self-Dithering Technique for High-Resolution SAR ADC Design
Author :
Lin He ; Lele Jin ; Jiaqi Yang ; Fujiang Lin ; Libin Yao ; Xicheng Jiang
Author_Institution :
Micro-/Nano-Electron. Syst. Integration Center, Univ. of Sci. & Technol. of China, Hefei, China
Abstract :
In this brief, a high-resolution successive-approximation-register analog-to-digital-conversion architecture for biomedical data acquisition is proposed. A filtered least-significant-bit segment is employed as a dither to improve the resolution. Theoretical analysis and behavioral simulations show that the error of a most-significant-bit segment can be converted into shaped noise if the input signal is sufficiently small. The proposed self-dithering technique can be used, together with averaging, to improve the signal-to-noise ratio and the differential nonlinearity (DNL) performance. The performance improvement is similar to that of a conventional nonsubtractive scheme using a uniform deterministic dither but with simplified hardware and reduced computation complexity.
Keywords :
analogue-digital conversion; computational complexity; data acquisition; analog-to-digital-conversion; biomedical data acquisition; computation complexity; differential nonlinearity performance; filtered least-significant-bit segment; high-resolution SAR ADC design; nonsubtractive scheme; self-dithering technique; signal-to-noise ratio; successive approximation register; uniform deterministic dither; Circuits and systems; Hardware; Noise; Noise shaping; Quantization (signal); Signal resolution; Solid state circuits; Analog-to-digital conversion; Analog-to-digital conversion (ADC); SAR ADC; biosensing system; data acquisition; deterministic dither; dither; hardware efficient; hardware-efficient; high resolution; high-resolution; nonsubtractive dithering; subtractive dithering; successive-approximation-register ADC (SAR ADC);
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2015.2468921
