An adaptive multi-modulus frequency divider

Author

Yuan Hengzhou ; Ma Zhuo ; Guo Yang

Author_Institution

Coll. of Comput. Sci., Nat. Univ. of Defense Technol., Changsha, China

fYear

2013

fDate

28-31 Oct. 2013

Firstpage

1

Lastpage

4

Abstract

The demand for high-speed low-power multi-modulus frequency divider is increasing in Phase-Locked Loop (PLL) design. In this paper, by combining the merits of traditional Johnson counter and Pulse-swallow frequency divider, we proposed a novel two-stage divider which can improve the operating frequency and decrease the power dissipation enormously. An adaptive component is built to set the divider in best power-saving mode. Based on the 40nm CMOS process, the frequency of this two-stage divider can reach 4GHz. The minimum power dissipation in divide-by-49 mode is 63μW@1GHz, or 156μW@4GHz. Compared with typical Johnson counter frequency divider, the frequency of the two-stage divider is improved about 1.6 times, while the power optimization ratio is 51.19%.

Keywords

CMOS integrated circuits; MMIC frequency convertors; UHF frequency convertors; UHF integrated circuits; field effect MMIC; frequency dividers; low-power electronics; CMOS process; Johnson counter; PLL; adaptive component; adaptive multimodulus frequency divider; frequency 1 GHz; high-speed low-power multimodulus frequency divider; phase-locked loop design; power dissipation; power-saving mode; pulse-swallow frequency divider; size 40 nm; two-stage divider; Frequency control; Frequency conversion; Frequency synthesizers; Phase locked loops; Power demand; Power dissipation; Radiation detectors;

fLanguage

English

Publisher

ieee

Conference_Titel

ASIC (ASICON), 2013 IEEE 10th International Conference on

Conference_Location

Shenzhen

ISSN

2162-7541

Print_ISBN

978-1-4673-6415-7

Type

conf

DOI

10.1109/ASICON.2013.6811984

Filename

6811984