High Speed Low Power True Single Phase Clock CMOS Divide by 2/3 Prescaler

被引:0
|
作者
Ji, Xincun [1 ]
Yan, Xu [1 ]
Guo Fengqi [1 ]
Guo, Yufeng [1 ]
机构
[1] Nanjing Univ Posts & Telecommun, Jiangsu Prov Engn Lab RF Integrat & Micropackagin, Nanjing, Jiangsu, Peoples R China
来源
CONFERENCE PROCEEDINGS OF 2017 INTERNATIONAL CONFERENCE ON CIRCUITS, DEVICES AND SYSTEMS (ICCDS) | 2017年
关键词
component; prescaler; true-single-phase-clock divider; low-power;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
A new true-single-phase-clock (TSPC) divide-by-2/3 prescaler is presented in this work. By merging one of the branches of the TSPC D flip-flops (DFF) and the modified dual-modulus control circuit, we can realize a divide-by-2/3 prescaler with only 5-stage TSPC logic gates and fewer transistors compared with the conventional designs. Analysis shows that the load capacitance at output of the proposed prescaler can be much reduced, and the prescaler can operate as fast as a single TSPC flip-flop when working in the divide-by-3 mode. The proposed prescaler and the recently published works are both simulated in a low power 65nm CMOS process. From the simulation results, it is shown that the proposed divide-by-2/3 prescaler demonstrates the highest power efficiency among the referenced designs.
引用
收藏
页码:80 / 83
页数:4
相关论文
共 50 条
  • [41] Package clock distribution design optimization for high-speed and low-power VLSI's
    Zhu, Q
    IEEE TRANSACTIONS ON COMPONENTS PACKAGING AND MANUFACTURING TECHNOLOGY PART B-ADVANCED PACKAGING, 1997, 20 (01): : 56 - 63
  • [42] Low Voltage and Low Power Divide-By-2/3 Counter Design Using Pass Transistor Logic Circuit Technique
    Hwang, Yin-Tsung
    Lin, Jin-Fa
    IEEE TRANSACTIONS ON VERY LARGE SCALE INTEGRATION (VLSI) SYSTEMS, 2012, 20 (09) : 1738 - 1742
  • [43] PCFL3: A low-power, high-speed, single-ended logic family
    Kanan, R
    Declercq, MJ
    IEEE JOURNAL OF SOLID-STATE CIRCUITS, 1999, 34 (09) : 1259 - 1269
  • [44] Design of Low Power, High Speed PLL Frequency Synthesizer using Dynamic CMOS VLSI Technology
    Nirmalraj, T.
    Radhakrishnan, S.
    Karn, Rakesh Kumar
    Pandiyan, S. K.
    2017 IEEE INTERNATIONAL CONFERENCE ON POWER, CONTROL, SIGNALS AND INSTRUMENTATION ENGINEERING (ICPCSI), 2017, : 1074 - 1076
  • [45] HIGH-SPEED AND LOW-POWER N(+)-P(+) DOUBLE-GATE SOI CMOS
    SUZUKI, K
    TANAKA, T
    TOSAKA, Y
    HORIE, H
    SUGII, T
    IEICE TRANSACTIONS ON ELECTRONICS, 1995, E78C (04) : 360 - 367
  • [46] Low Power CMOS Full Adder Cells based on Alternative Logic for High-Speed Arithmetic Applications
    Subramanian, Sriram Sundar
    Gandhi, Mahendran
    INFORMACIJE MIDEM-JOURNAL OF MICROELECTRONICS ELECTRONIC COMPONENTS AND MATERIALS, 2024, 54 (03):
  • [47] Highly stable and manufacturable body-tied SOI technology for high speed and low power CMOS devices
    Kim, YW
    Kang, HS
    Oh, CB
    Oh, MH
    Yoo, SH
    Kim, BS
    Park, S
    Suh, KP
    JOURNAL OF THE KOREAN PHYSICAL SOCIETY, 2003, 42 (02) : 206 - 209
  • [48] A 3 V low power 156/622/1244 Mbps CMOS parallel clock and data recovery circuit for optical communications
    Seo, HM
    Woo, CG
    Oh, SW
    Jung, SW
    Choi, P
    IEICE TRANSACTIONS ON FUNDAMENTALS OF ELECTRONICS COMMUNICATIONS AND COMPUTER SCIENCES, 2000, E83A (08) : 1720 - 1727
  • [49] Low-Voltage and Low-Power True-Single-Phase 16-Transistor Flip-Flop Design
    Lin, Jin-Fa
    Hong, Zheng-Jie
    Wu, Jun-Ting
    Tung, Xin-You
    Yang, Cheng-Hsueh
    Yen, Yu-Cheng
    SENSORS, 2022, 22 (15)
  • [50] A design for high-speed low-power CMOS fully parallel content-addressable memory macros
    Miyatake, H
    Tanaka, M
    Mori, Y
    IEEE JOURNAL OF SOLID-STATE CIRCUITS, 2001, 36 (06) : 956 - 968
12345