تحلیل و بررسی تأثیر پارامترهای طراحی فلیپفلاپ استاتیک بر مشخصههای زمانی و توان مصرفی آن در تکنولوژی 16 نانومتر
محورهای موضوعی : مهندسی برق و کامپیوتراحسان محمودی 1 , مرتضی قلی پور 2
1 - دانشگاه صنعتی نوشیروانی بابل
2 - دانشگاه صنعتی نوشیروانی بابل
کلید واژه: پارامترهای زمانیتوان مصرفیفلیپفلاپ استاتیک,
چکیده مقاله :
فلیپفلاپ یکی از عناصر مهم در طراحی مدارهای دیجیتال است که کارایی آن در سرعت و توان مصرفی سیستم بسیار تأثیرگذار میباشد. در این مقاله با انجام شبیهسازیهای مناسب، پارامترهای زمانی فلیپفلاپ استاتیک به دست آمده و تأثیر ابعاد ترانزیستورهای مختلف بر این پارامترها مورد بررسی قرار گرفته است. سپس با تغییر ولتاژ تغذیه و پارامترهای فرایند ساخت، میزان تأثیر تغییرات این عوامل بر کارایی فلیپفلاپ مورد ارزیابی قرار گرفته است. عرض ترانزیستورهای مدار بر اساس دستیابی به حاصلضرب انرژی- تأخیر (EDP) و حاصلضرب توان- تأخیر (PDP) مطلوب در دو حالت به صورت مجزا تعیین شدهاند. سپس تأثیر تغییرات ولتاژ بر افزایش EDP و PDP در مقایسه با فلیپفلاپ پایه مورد بررسی و ارزیابی قرار گرفته است. فلیپفلاپ مورد بررسی در این مقاله فلیپفلاپ استاتیک نوع D میباشد. شبیهسازیها با استفاده از نرمافزار HSPICE در تکنولوژی 16 نانومتر و در فرکانس نامی GHz 1 انجام شده است.
Flip-flop is one of the important elements in the digital circuit’s design, which its performance affects the speed and power of the system. In this paper, appropriate simulations are used to obtain the timing parameters of the static flip-flop and investigate the effect of the width of different transistors on these parameters. Then, the effects of the supply voltage and manufacturing process parameters variation on the performance of the flip-flop are investigated. The widths of transistors are determined based on the desired energy-delay product (EDP) and power-delay product (PDP) for these two cases separately. Then, the effect of voltage variations on the increase of EDP and PDP are investigated compared to the base flip-flop. We used a static D-type flip-flop in our simulations. The simulations were performed using the HSPICE in 16 nm technology node at 1 GHz frequency.
[1] S. Bernard, M. Belleville, J. Legat, A. Valentian, and D. Bol, "Ultra-wide voltage range pulse-triggered flip-flops and register file with tunable energy-delay target in 28 nm UTBB-FDSOI," Microelectronics J., vol. 57, Issue C, pp. 76-86, Nov. 2016.
[2] H. Jiang, H. Zhang, T. R. Assis, B. Narasimham, B. L. Bhuva, W. T. Holman, and L. W. Massengill, "Single-event performance of sense-amplifier based flip-flop design in a 16-nm bulk FinFET CMOS process," IEEE Trans. on Nuclear Science, vol. 64, no. 1, pp. 477-482, Dec. 2017.
[3] L. Yang, X. Zhang, Q. Zhang, M. Tan, and Y. Yu, "A high-speed small-area pixel 16×16 ISFET array design using 0.35-μm CMOS process," Microelectronics J., vol. 79, pp. 107-112, Sept. 2018.
[4] Y. Li, L. Chen, I. Nofal, M. Chen, and R. Wong, "Modeling and analysis of single-event transient sensitivity of a 65 nm clock tree," Microelectronics Reliability, vol. 87, pp. 24-32, Aug. 2018.
[5] M. Y. Tsai, P. Y. Kuo, J. F. Lin, and M. H. Sheu, "An ultra-low-power true single-phase clocking flip-flop with improved hold time variation using logic structure reduction scheme," in Proc. IEEE Int. Symp. on Circuits and Systems, ISCAS’18, 4 pp., Florence, Italy, 27-30 May 2018.
[6] B. Aparna and V. Anandi, "Design of a D flip flop for optimization of power dissipation using GDI technique," in Proc. 2nd IEEE Int. Conf. on Recent Trends in Electronics, Information & Communication Technology, RTEICT’17, pp. 172-177 Bangalore, India, 19-20 May 2017.
[7] H. NathSaha et al., "Performance optimization in flip flop circuit design," in Proc. IEEE 8th Annual Computing and Communication Workshop and Conf., CCWC’18, pp. 421-423, Las Vegas, NV, USA, 8-10 Jan. 2018.
[8] T. Lee, D. Z. Pan, and J. S. Yang, "Clock network optimization with multibit flip-flop generation considering multicorner multimode timing constraint," IEEE Trans. on Computer-Aided Design of Integrated Circuits and Systems, vol. 37, no. 1, pp. 245-256, Apr. 2018.
[9] S. Heo and R. Krashinsky, "Activity-sensitive flip-flop and latch selection for reduced energy," IEEE Trans. on Very Large Scale Integration (VLSI) Systems, vol. 15, no. 9, pp. 1060-1064, Sept. 2007.
[10] Y. T. Liu, L. Y. Chiou, and S. J. Chang, "Energy-efficient adaptive clocking dual edge sense-amplifier flip-flop," in Proc. IEEE Int. Symp. Circuits Systems, ISCAS’06, pp. 4329-4332, 21-24 May 2006.
[11] P. Zhao, T. K. Darwish, and M. A. Bayoumi, "High-performance and low-power conditional discharge flip-flop," IEEE Trans. Very Large Scale Integr. (VLSI) Syst., vol. 12, no. 5, pp. 477-484, May 2004.
[12] N. H. E. Weste and D. M. Harris, CMOS VLSI Design-a Circuits and Systems Perspective, 4th Edition, Addison-Wesley, 2015.
[13] A. R. Palaniappan and L. Siek, "Wide-input dynamic range 1 MHz clock ultra-low supply flip-flop," Electronics Letters, vol. 54, no. 15, pp. 938-939, 12 Jun. 2018.
[14] P. Bhattacharjee, B. Nath, and A. Majumder, "LECTOR based clock gating for low power multi-stage flip flop applications," in Proc. Int. Conf. on Electronics, Information, and Communication, ICEIC’17, pp. 106-109, Phuket, Thailand, 11-14 Jan. 2017.
[15] K. Liao, X. Cui, N. Liao, and T. Wang, "Design of D flip-flops with low power-delay product based on FinFET," in Proc. 12th IEEE Int. Conf. on Solid-State and Integrated Circuit Technology, ICSICT’14, 3 pp. 1-3, Guilin, China, 28-31 Oct. 2014.
[16] P. Dobriyal, K. Sharma, M. Sethi, and G. Sharma, "A high performance D-flip flop design with low power clocking system using MTCMOS technique," in Proc. 3rd IEEE Int. Advance Computing Conf., IACC’13, pp. 1524-1528, Ghaziabad, India, 22-23 Feb. 2013.
[17] M. A. Sobhan Bhuiyan, A. Mahmoudbeik, T. I. Badal, M. Bin Ibne Reaz, and L. F. Rahman, "Low power D flip-flop serial in/parallel out based shift register," in Proc. Int. Conf. on Advances in Electrical, Electronic and Systems Engineering, ICAEES’16, pp. 180-184, Putrajaya, Malaysia, 14-16 Nov. 2016.
[18] S. D. Pyle, H. Li, and R. F. DeMara, "Compact low-power instant store and restore D flip-flop using a self-complementing spintronic device," Electronics Letters, vol. 52, no. 14, pp. 1238-1240, 26 May 2016.
[19] -, Predictive Technology Model, [Online]. Available: http://ptm.asu.edu/
