Design and Development of Efficient Energy Systems. Группа авторов

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Design and Development of Efficient Energy Systems - Группа авторов


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The longest path arrival time form input to pin p[30] is 5476 ps shown in Table 2.8.

      Vedic multiplier replaces the underlying cell by compressors logic, made up of adder block. Utilization of compressor greatly reduces the wiring resource save area. The leakage power of the Vedic multiplier is larger than other compare multipliers but shows very low dynamic power consumption. Dadda multiplier requires maximum power to reduce the delay 2.56ns. A Vedic multiplier attains significant reduction in dynamic power requirement and delay of multiplication architecture. Cell count of VM is 139 which is much smaller than other multipliers.

      2.4.5 Applications of Multiplier

      The present work Vedic multiplier finds application to implement the architecture of the following [21–25]

      1 1) High-speed signal processing

      2 2) DSP based application

      3 3) DWT and DCT transformation

      4 4) FIT and IIR filter

      5 5) Multirate signal processing

      6 6) Up-Down converters

      7 7) Multiply - Accumulate unit

      An efficient productive strategy for multiplication based on Urdhva Tiryakbhyam Sutra (Algorithm) in view of Vedic mathematics is implemented in this paper with Verilog HDL. Here a fast 8-bit multiplier is implemented that incorporates architecture of compressor. Compressor is a derived structure of full adder and half adder, map multiple input to lesser number of output signals. Hierarchical multiplier structure and shows the computational speed by offered by Vedic methods. Essential inspiration of this work is to decrease the delay in complex multiplication achieve 2.637 ns. We can deduce that the compressor-based architecture of Vedic math’s multiplier is more favorable than conventional multipliers and preferred in complex algorithm implementation. Hence, we have concluded that Instance Power usage of 8x8 Vedic Multiplier is 40.48% and 16x16 Vedic Multiplier is 62.22%. The Net Power usage of 8x8 Vedic Multiplier is 82.24%, and the 16x16 Vedic Multiplier is 86.85%.

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      15. Ram, G. C., Lakshmanna, Y. R., Rani, D. S., & Sindhuri, K. B. (2016, March). Area efficient modified vedic multiplier. In International Conference on Circuit, Power and Computing Technologies (ICCPCT). 2006, IEEE (pp. 1-5).

      16. Prabhu, E., Mangalam, H., & Gokul, P. R. (2019). A delay efficient vedic multiplier. Proceedings of the National Academy of Sciences, India Section A: Physical Sciences, 89(2), 257-268.

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      18. Shukla, V., Singh, O. P., Mishra, G. R., & Tiwari, R. K. (2020). A Novel Approach for Reversible Realization of 4× 4 Bit Vedic Multiplier Circuit. In Advances in VLSI, Communication, and Signal Processing, 2020, Springer, Singapore, (pp. 733-745).

      19. Karthikeyan, S., & Jagadeeswari, M. (2020). Performance improvement of elliptic curve cryptography system using low power, high speed 16× 16 Vedic multiplier based on reversible logic. Journal of Ambient Intelligence and Humanized Computing, 1-10.

      20. Koul, R., Yadav, M., & Suneja, K. (2020). Novel FPGA-Based Hardware Design of Canonical Signed Digit Matrix Multiplier and Its Comparative Analysis with Other Multipliers. In International Conference on Artificial Intelligence: Advances and Applications 2019, Springer, Singapore (pp. 65-75).

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      23. Panda, S. K., Das, R., & Sahoo, T. R. (2015). VLSI implementation of vedic multiplier


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