Title :
"Split ADC" architecture for deterministic digital background calibration of a 16-bit 1-MS/s ADC
Author :
McNeill, John ; Coln, Michael C W ; Larivee, Brian J.
Author_Institution :
Worcester Polytech. Inst., MA, USA
Abstract :
Self-calibration in approximately 10 000 conversions is demonstrated in a 16-bit, 1-MS/s algorithmic analog-to-digital converter (ADC). Continuous digital background calibration is enabled by introduction of a "split ADC" architecture, in which the die area of a single ADC design is split into two independent converters, each converting the same input signal. The two independent outputs are averaged to produce the ADC output code. The difference of the two outputs provides information for the background calibration process. Since both ADCs convert the same input, when correctly calibrated their outputs should be equal and the difference should be zero. Any nonzero difference provides information to an error estimation process which adjust calibration parameters in each ADC. For the specific realization of an algorithmic ADC described in this paper, a multiple residue mode amplifier is used to ensure different decision trajectories and provide valid calibration information. The analog sub-system of the ADC is implemented in 0.25-μm CMOS, consumes 105 mW, and has a die size of 1.2 mm × 1.4 mm.
Keywords :
CMOS digital integrated circuits; amplifiers; analogue-digital conversion; calibration; 0.25 micron; 1.2 mm; 1.4 mm; 105 mW; 16 bit; ADC output code; analog sub-system; analog-to-digital conversion; analog-to-digital converter; digital background calibration; error estimation process; mixed analog-digital integrated circuits; multiple residue mode amplifier; self-calibration; split ADC architecture; Analog integrated circuits; Analog-digital conversion; Calibration; Data mining; Digital integrated circuits; Error analysis; Error correction; Helium; Signal design; Signal processing; Adaptive systems; analog-to-digital conversion; calibration; digital background calibration; mixed analog–digital integrated circuits; self-calibrating;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2005.856291
