A 2.5 GS/s 14-bit D/A converter(DAC) with 8 to 1 MUX is presented. This 14-bit DAC uses a "5+9"segment PMOS current-steering architecture. A bias circuit which ensures the PMOS current source obtains a larger out...A 2.5 GS/s 14-bit D/A converter(DAC) with 8 to 1 MUX is presented. This 14-bit DAC uses a "5+9"segment PMOS current-steering architecture. A bias circuit which ensures the PMOS current source obtains a larger output impedance under every PVT(process, source voltage and temperature) corner is also presented. The8 to 1 MUX has a 3 stage structure, and a proper timing sequence is designed to ensure reliable data synthesis. A DEM function which is merged with a "5-31"decoder is used to improve the DAC's dynamic performance. This DAC is embedded in a 2.5 GHz direct digital frequency synthesizer(DDS) chip, and is implemented in a 0.18 m CMOS technology, occupies 4.86 2. 28 mm-2 including bond pads(DAC only), and the measured performance is SFDR 〉 40 d B(with and without DEM) for output signal frequency up to 1 GHz. Compared with other present published DACs with a non-analog-resample structure(means return-to-zero or quad-switch structure is unutilized),this paper DAC's clock frequency(2.5 GHz) and higher output frequency SFDR(〉 40 d B, up to 1 GHz) has some competition.展开更多
基金Project supported by the National Natural Science Foundation of China(Nos.61006027,61176030)the Research Foundation of Key Laboratory of Analog Integrated Circuit(Nos.9140C0902120C09034,9140c090204130c09042)the Fundamental Research Funds for the Central Universities of China(No.ZYGX2012J003)
文摘A 2.5 GS/s 14-bit D/A converter(DAC) with 8 to 1 MUX is presented. This 14-bit DAC uses a "5+9"segment PMOS current-steering architecture. A bias circuit which ensures the PMOS current source obtains a larger output impedance under every PVT(process, source voltage and temperature) corner is also presented. The8 to 1 MUX has a 3 stage structure, and a proper timing sequence is designed to ensure reliable data synthesis. A DEM function which is merged with a "5-31"decoder is used to improve the DAC's dynamic performance. This DAC is embedded in a 2.5 GHz direct digital frequency synthesizer(DDS) chip, and is implemented in a 0.18 m CMOS technology, occupies 4.86 2. 28 mm-2 including bond pads(DAC only), and the measured performance is SFDR 〉 40 d B(with and without DEM) for output signal frequency up to 1 GHz. Compared with other present published DACs with a non-analog-resample structure(means return-to-zero or quad-switch structure is unutilized),this paper DAC's clock frequency(2.5 GHz) and higher output frequency SFDR(〉 40 d B, up to 1 GHz) has some competition.
