Numerical model for 32-bit magnonic ripple carry adder

Umberto Garlando; Qi Wang; Oleksandr Dobrovolskiy; Andrii Chumak; Fabrizio Riente

doi:10.1109/TETC.2023.3238581

Numerical model for 32-bit magnonic ripple carry adder

Umberto Garlando
, Qi Wang
, Oleksandr Dobrovolskiy
, Andrii Chumak
, Fabrizio Riente (Corresponding author)

Nanomagnetism and Magnonics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

In CMOS-based electronics, the most straightforward way to implement a summation operation is to use the ripple carry adder (RCA). Magnonics, the field of science concerned with data processing by spin waves and their quanta magnons, recently proposed a magnonic half-adder that can be considered as the simplest magnonic integrated circuit. Here, we develop a computation model for the magnonic basic blocks to enable the design and simulation of magnonic gates and magnonic circuits of arbitrary complexity and demonstrate its functionality on the example of a 32-bit integrated RCA. It is shown that the RCA requires the utilization of additional regenerators based on magnonic directional couplers with embedded amplifiers to normalize the magnon signals in-between the half-adders. The benchmarking of large-scale magnonic integrated circuits is performed. The energy consumption of 30 nm-based magnonic 32-bit adder can be as low as 961 aJ per operation with taking into account all required amplifiers.

Original language	English
Pages (from-to)	679-688
Number of pages	10
Journal	IEEE Transactions on Emerging Topics in Computing
Volume	11
Issue number	3
DOIs	https://doi.org/10.1109/TETC.2023.3238581
Publication status	Published - Jul 2023

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Austrian Fields of Science 2012

103017 Magnetism

Keywords

Adders
Compact model
Couplings
Directional couplers
Dispersion
Integrated circuit modeling
Logic gates
Magnon
Magnonic circuits
Magnonics
Spintronics
spintronics
magnon
magnonic circuits

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10.1109/TETC.2023.3238581Licence: CC BY 4.0

https://arxiv.org/abs/2109.12973

Cite this

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title = "Numerical model for 32-bit magnonic ripple carry adder",

abstract = "In CMOS-based electronics, the most straightforward way to implement a summation operation is to use the ripple carry adder (RCA). Magnonics, the field of science concerned with data processing by spin waves and their quanta magnons, recently proposed a magnonic half-adder that can be considered as the simplest magnonic integrated circuit. Here, we develop a computation model for the magnonic basic blocks to enable the design and simulation of magnonic gates and magnonic circuits of arbitrary complexity and demonstrate its functionality on the example of a 32-bit integrated RCA. It is shown that the RCA requires the utilization of additional regenerators based on magnonic directional couplers with embedded amplifiers to normalize the magnon signals in-between the half-adders. The benchmarking of large-scale magnonic integrated circuits is performed. The energy consumption of 30 nm-based magnonic 32-bit adder can be as low as 961 aJ per operation with taking into account all required amplifiers.",

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author = "Umberto Garlando and Qi Wang and Oleksandr Dobrovolskiy and Andrii Chumak and Fabrizio Riente",

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AU - Garlando, Umberto

AU - Wang, Qi

AU - Dobrovolskiy, Oleksandr

AU - Chumak, Andrii

AU - Riente, Fabrizio

PY - 2023/7

Y1 - 2023/7

N2 - In CMOS-based electronics, the most straightforward way to implement a summation operation is to use the ripple carry adder (RCA). Magnonics, the field of science concerned with data processing by spin waves and their quanta magnons, recently proposed a magnonic half-adder that can be considered as the simplest magnonic integrated circuit. Here, we develop a computation model for the magnonic basic blocks to enable the design and simulation of magnonic gates and magnonic circuits of arbitrary complexity and demonstrate its functionality on the example of a 32-bit integrated RCA. It is shown that the RCA requires the utilization of additional regenerators based on magnonic directional couplers with embedded amplifiers to normalize the magnon signals in-between the half-adders. The benchmarking of large-scale magnonic integrated circuits is performed. The energy consumption of 30 nm-based magnonic 32-bit adder can be as low as 961 aJ per operation with taking into account all required amplifiers.

AB - In CMOS-based electronics, the most straightforward way to implement a summation operation is to use the ripple carry adder (RCA). Magnonics, the field of science concerned with data processing by spin waves and their quanta magnons, recently proposed a magnonic half-adder that can be considered as the simplest magnonic integrated circuit. Here, we develop a computation model for the magnonic basic blocks to enable the design and simulation of magnonic gates and magnonic circuits of arbitrary complexity and demonstrate its functionality on the example of a 32-bit integrated RCA. It is shown that the RCA requires the utilization of additional regenerators based on magnonic directional couplers with embedded amplifiers to normalize the magnon signals in-between the half-adders. The benchmarking of large-scale magnonic integrated circuits is performed. The energy consumption of 30 nm-based magnonic 32-bit adder can be as low as 961 aJ per operation with taking into account all required amplifiers.

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KW - Dispersion

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KW - Magnonic circuits

KW - Magnonics

KW - Spintronics

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Numerical model for 32-bit magnonic ripple carry adder

Abstract

UN SDGs

Austrian Fields of Science 2012

Keywords

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