In the design of modern processor chips, proper clock distribution is a very important aspect which impacts the chip performance. It is the active cell of delay circuits and cells with variable delay that have the major involvement in clock distribution, thereby deciding the time slacks of all functionalities inside the chip as they help in proper input to output signal transmission with the adjustment of variable timing delays and monitor the output signal to have equal rise/fall time, which most of the existing delay elements fail to deliver. Therefore in this article, we have proposed an input vector based design that operates variable delay with balanced rise time and fall time for the output signal. We have also estimated the delay and output voltage in terms of a mathematical model. This new configuration is executed across the commercial platform of Cadence Virtuoso® using 90nm technology node and by taking 1GHz input signal and power supply 1.1V. The execution outcome confirms the desired features of our proposed design are correctly upheld under typical conditions and even in process corner variations.

vector-controlled circuit design; variable delay cell, Rise/Fall time; Processor Clock; CMOS process technology

Dong, T., Dobrev, V., Kolev, T., Rieben, R., Tomov, S., & Dongarra, J. (2014, May). A step towards energy efficient computing: Redesigning a hydrodynamic application on CPU-GPU. In 2014 IEEE 28th International Parallel and Distributed Processing Symposium (pp. 972-981). IEEE.

Chen, W., & Dömer, R. (2015). Out-of-order Parallel Discrete Event Simulation for Electronic System-level Design. Springer International Publishing, https://link.springer.com/content/pdf/10.1007/978-3-319-08753-5.pdf

Anju, C., & Pande, K. S. (2012). Low Power GALS Interface Implementation with Stretchable Clocking Scheme. International Journal of Computer Science Issues (IJCSI), 9(4), 209. Download Link

Dhirubhai, L. M., & Pande, K. S. (2019, July). Critical Path Delay Improvement in Logic Circuit Operated at Subthreshold Region. In 2019 International Conference on Communication and Electronics Systems (ICCES) (pp. 633-637). IEEE.

Abas, M. A., Russell, G., & Kinniment, D. J. (2007). Embedded high-resolution delay measurement system using time amplification. IET Computers & Digital Techniques, 1(2), 77-86.

Abas, M. A., Russell, G., & Kinniment, D. J. (2007). Built-in time measurement circuits–a comparative design study. IET Computers & Digital Tech-niques, 1(2), 87-97.

Banerjee, A., & Das, D. K. (2016). A New Squarer design with reduced area and delay. IET Computers & Digital Techniques, 10(5), 205-214.

Mahapatra, N. R., Tareen, A., & Garimella, S. V. (2002). Comparison and analysis of delay elements. In Circuits and Systems, 2002. MWSCAS-2002. The 2002 45th Midwest Symposium on (Vol. 2, pp. II-II). IEEE.

Zhang, X., & Sridhar, R. (1994, September). CMOS wave pipelining using transmission-gate logic. In Proceedings Seventh Annual IEEE International ASIC Conference and Exhibit (pp. 92-95). IEEE.

Mahapatra, N. R., Garimella, S. V., & Tareen, A. L. W. I. N. (2000, April). An empirical and analytical comparison of delay elements and a new delay element design. In Proceedings IEEE Computer Society Workshop on VLSI 2000. System Design for a System-on-Chip Era (pp. 81-86). IEEE.

Jovanović, G. S., & Stojčev, M. K. (2006). Current starved delay element with symmetric load. International journal of electronics, 93(03), 167-175.

Moyer, G. C., Clements, M., & Liu, W. (1996). Precise delay generation using the Vernier technique. Electronics letters, 32(18), 1658-1659.

Li, G. H., & Chou, H. P. (2007, November). A high resolution time-to-digital converter using two-level vernier delay line technique. In 2007 IEEE Nuclear Science Symposium Conference Record (Vol. 1, pp. 276-280). IEEE.

Johnson, M. G., & Hudson, E. L. (1988). A variable delay line PLL for CPU-coprocessor synchronization. IEEE Journal of Solid-State Circuits, 23(5), 1218-1223.

Maymandi-Nejad, M., & Sachdev, M. (2003). A digitally programmable delay element: design and analysis. IEEE transactions on very large scale integration (VLSI) systems, 11(5), 871-878.

Maymandi-Nejad, M., & Sachdev, M. (2005). A monotonic digitally controlled delay element. IEEE Journal of Solid-State Circuits, 40(11), 2212-2219.

Kobenge, S. B., & Yang, H. (2009). A power efficient digitally programmable delay element for low power VLSI applications. In Quality Electronic Design, 2009. ASQED 2009. 1st Asia Symposium on (pp. 83-87). IEEE.

Sadhu, A., Bhattacharjee, P., & Koley, S. (2014). Performance Estimation of VLSI Design. Journal of VLSI Design Tools & Technology, 4(2), 59-66. https://doi.org/10.37591/jovdtt.v4i2.3167

Rajeswari, P., Shekar, G., Devi, S., & Purushothaman, A. (2018). Geometric Programming-Based Power Optimization and Design Automation for a Digitally Controlled Pulse Width Modulator. Circuits, Systems, and Signal Processing, 37(9), 4049-4064. https://link.springer.com/article/10.1007/s00034-017-0734-z

Nose, K., Chae, S. I., & Sakurai, T. (2000). Voltage dependent gate capacitance and its impact in estimating power and delay of CMOS digital circuits with low supply voltage (poster session). In Proceedings of the 2000 international symposium on Low power electronics and design (pp. 228-230). ACM. https://doi.org/10.1145/344166.344601

90nm CMOS based Process Design Kit Download Link

Andreani, P., Bigongiari, F., Roncella, R., Saletti, R., & Terreni, P. (1999). A digitally controlled shunt capacitor CMOS delay line. Analog Integrated Circuits and Signal Processing, 18(1), 89-96. https://doi.org/10.1023/A:1008359721539

Mondal J, A., A. Majumder, B. K. Bhattacharyya & P. Chakraborty. (2017). A Process Aware Delay Circuit with Reduce Impact of Input Switching at GHz Frequencies. IEEE VLSI Circuits and Systems Letters 3(2), 6-12. Download Link

Kang, S. M., & Leblebici, Y. (2003). CMOS digital integrated circuits. Tata McGraw-Hill Education. Download Link

Xiang, Q. (2003). U.S. Patent No. 6,600,170. Washington, DC: U.S. Patent & Trademark Office.

Millar, R., & King, T. (1993). Students’ understanding of voltage in simple series electric circuits. International Journal of Science Education, 15(3), 339-349.

Roy, A., Ender, F., Azadmehr, M., Ta, B. Q., & Aasmundtveit, K. E. (2017, July). Design considerations of CMOS micro-heaters to directly synthesize carbon nanotubes for gas sensing ap-plications. In 2017 IEEE 17th International Conference on Nanotechnology (IEEE-NANO) (pp. 828-833). IEEE.

Quantus RC Extraction Source Link

Saint, C., & Saint, J. (2002). IC mask design: Essential layout techniques. New York: McGraw-Hill.

Martin-Gonthier, P., Havard, E., & Magnan, P. (2010). Custom transistor layout design techniques for random telegraph signal noise reduction in CMOS image sensors. Electronics Letters, 46(19), 1323-1324.

Megalingam, R. K., & Lal, L. S. (2014, April). Piezoresistive MEMS pressure sensors using Si, Ge, and SiC diaphragms: A VLSI layout optimization. In 2014 International Conference on Communication and Signal Processing (pp. 597-601). IEEE.

Geiger, R. L., Allen, P. E., & Strader, N. R. (1990). VLSI design techniques for analog and digital circuits (Vol. 90). New York: McGraw-Hill.