Title :
A low-power CMOS nine-channel 40-MHz binary detection system with self-calibrated 500-μV offset
Author :
Leme, Carlos Azeredo ; Silva, José ; Rodrigo, Paulo ; da Franca, José E.
Author_Institution :
Centre of Microsyst., Inst. Superior Tecnico, Lisbon, Portugal
fDate :
4/1/1998 12:00:00 AM
Abstract :
For application in high-energy physics experiments, this paper describes the design of a nine-channel binary detection system featuring a fully differential 300-μW, 40-MHz comparator whose offset voltage is reduced to less than 500 μV by means of a digitally controlled calibration system. Besides the comparator, each channel also includes an input waveshaping high-pass filter for improved detection performance in the particle-radiated operating environment. To save area and power, this is realized by a passive switched-capacitor polyphase network with time-interleaved operation. Two prototype chips have been realized in a 1.2-μm CMOS technology. One chip includes nine filter-comparator channels that occupy 0.4 mm2 and at 40 MHz dissipate about 2.7 mW. The other chip contains the calibration system that generates all control signals for offset correction of the filter/comparator channels and occupies 1.4 mm2
Keywords :
CMOS analogue integrated circuits; calibration; comparators (circuits); nuclear electronics; particle detectors; switched capacitor networks; 1.2 micron; 2.7 mW; 300 muW; 40 MHz; 500 muV; binary detection system; comparator; digitally controlled calibration system; filter-comparator channels; high-energy physics experiments; input waveshaping high-pass filter; low-power CMOS; offset correction; particle-radiated operating environment; self-calibrated offset; switched-capacitor polyphase network; time-interleaved operation; CMOS technology; Calibration; Control systems; Energy resolution; Energy states; Finite impulse response filter; Physics; Power dissipation; Signal resolution; Silicon;
Journal_Title :
Solid-State Circuits, IEEE Journal of
