A low-Voltage 10-bit CMOS DAC in 0.01-mm/sup 2/ die area

Abstract

A low-voltage 10-bit digital-to-analog converter (DAC) for static/dc operation is fabricated in a standard 0.18-/spl mu/m CMOS process. The DAC is optimized for large integrated circuit systems where possibly dozens of such DAC would be employed for the purpose of digitally controlled analog circuit calibration. The DAC occupies 110 /spl mu/m/spl times/94 /spl mu/m die area. A segmented R-2R architecture is used for the DAC core in order to maximize matching accuracy for a minimal use of die area. A pseudocommon centroid layout is introduced to overcome the layout restrictions of conventional common centroid techniques. A linear current mirror is proposed in order to achieve linear output current with reduced voltage headroom. The measured differential nonlinearity by integral nonlinearity (DNL/INL) is better than 0.7/0.75 LSB and 0.8/2 LSB for 1.8-V and 1.4-V power supplies, respectively. The DAC remains monotonic (|DNL|<1 LSB) as INL reaches 4 LSB down to 1.3-V operation. The DAC consumes 2.2 mA of current at all supply voltage settings.