Design of a laminated current cell relocation 12-bit CMOS D/A converter with a high output impedance technique and a merged switching logic

Junho Moon; Minkyu Song; Seungchul Shin; Kyungho Moon; Byungha Park

doi:10.1007/s10470-009-9392-9

Design of a laminated current cell relocation 12-bit CMOS D/A converter with a high output impedance technique and a merged switching logic

Junho Moon, Minkyu Song, Seungchul Shin, Kyungho Moon, Byungha Park

Division of System Semiconductor

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

A compact and low power 12-bit 300 MS/s current steering CMOS D/A converter is presented. The architecture of the D/A converter is based on the current steering 6 + 6 segmented type with a laminated current cell relocation technique. In order to improve the linearity and glitch noise, a high output impedance analog current cell is designed. Furthermore, for the purpose of reducing the chip area and power dissipation, a noble merged switching logic and a compact layout technique are proposed. To verify its performance, the chip was fabricated with 0.13 lm thick-gate 1-poly 6-metal N-well Samsung CMOS technology. The effective chip area is 0.26 mm² (510 × 510 μm) with a power consumption of 100 mW. The measured INL and DNL are within ±3LSB and ±1LSB, respectively. The measured SFDR is about 70 dB, when the input frequency is 1 MHz at a clock frequency of 300 MHz.

Original language	English
Pages (from-to)	407-414
Number of pages	8
Journal	Analog Integrated Circuits and Signal Processing
Volume	63
Issue number	3
DOIs	https://doi.org/10.1007/s10470-009-9392-9
State	Published - Jun 2010

Keywords

Compact layout technique
Current steering DAC
Laminated current cell relocation
Merged switching logic

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10.1007/s10470-009-9392-9

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title = "Design of a laminated current cell relocation 12-bit CMOS D/A converter with a high output impedance technique and a merged switching logic",

abstract = "A compact and low power 12-bit 300 MS/s current steering CMOS D/A converter is presented. The architecture of the D/A converter is based on the current steering 6 + 6 segmented type with a laminated current cell relocation technique. In order to improve the linearity and glitch noise, a high output impedance analog current cell is designed. Furthermore, for the purpose of reducing the chip area and power dissipation, a noble merged switching logic and a compact layout technique are proposed. To verify its performance, the chip was fabricated with 0.13 lm thick-gate 1-poly 6-metal N-well Samsung CMOS technology. The effective chip area is 0.26 mm2 (510 × 510 μm) with a power consumption of 100 mW. The measured INL and DNL are within ±3LSB and ±1LSB, respectively. The measured SFDR is about 70 dB, when the input frequency is 1 MHz at a clock frequency of 300 MHz.",

keywords = "Compact layout technique, Current steering DAC, Laminated current cell relocation, Merged switching logic",

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AU - Moon, Junho

AU - Song, Minkyu

AU - Shin, Seungchul

AU - Moon, Kyungho

AU - Park, Byungha

PY - 2010/6

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N2 - A compact and low power 12-bit 300 MS/s current steering CMOS D/A converter is presented. The architecture of the D/A converter is based on the current steering 6 + 6 segmented type with a laminated current cell relocation technique. In order to improve the linearity and glitch noise, a high output impedance analog current cell is designed. Furthermore, for the purpose of reducing the chip area and power dissipation, a noble merged switching logic and a compact layout technique are proposed. To verify its performance, the chip was fabricated with 0.13 lm thick-gate 1-poly 6-metal N-well Samsung CMOS technology. The effective chip area is 0.26 mm2 (510 × 510 μm) with a power consumption of 100 mW. The measured INL and DNL are within ±3LSB and ±1LSB, respectively. The measured SFDR is about 70 dB, when the input frequency is 1 MHz at a clock frequency of 300 MHz.

AB - A compact and low power 12-bit 300 MS/s current steering CMOS D/A converter is presented. The architecture of the D/A converter is based on the current steering 6 + 6 segmented type with a laminated current cell relocation technique. In order to improve the linearity and glitch noise, a high output impedance analog current cell is designed. Furthermore, for the purpose of reducing the chip area and power dissipation, a noble merged switching logic and a compact layout technique are proposed. To verify its performance, the chip was fabricated with 0.13 lm thick-gate 1-poly 6-metal N-well Samsung CMOS technology. The effective chip area is 0.26 mm2 (510 × 510 μm) with a power consumption of 100 mW. The measured INL and DNL are within ±3LSB and ±1LSB, respectively. The measured SFDR is about 70 dB, when the input frequency is 1 MHz at a clock frequency of 300 MHz.

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Design of a laminated current cell relocation 12-bit CMOS D/A converter with a high output impedance technique and a merged switching logic

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Keywords

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