Verification for Field-coupled Nanocomputing Circuits

Marcel Walter; Robert Wille; Frank Sill Torres; Daniel Große; Rolf Drechsler

Verification for Field-coupled Nanocomputing Circuits

Marcel Walter, Robert Wille, Frank Sill Torres, Daniel Große, Rolf Drechsler

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

With the decline of Moore's Law, several post - CMOS technologies are currently under heavy consideration. Promising candidates can be found in the class of Field-coupled Nanocomputing (FCN) devices as they allow for highest processing performance with tremendously low energy dissipation. With upcoming design automation in this domain, the need for formal verification approaches arises. Unfortunately, FCN circuits come with certain domain-specific properties that render conventional methods for the verification non-applicable. In this paper, we investigate this issue and propose a verification approach for FCN circuits that addresses this problem. For the first time, this provides researchers and engineers with an automatic method that allows them to check whether an obtained FCN circuit design indeed implements the given / desired function. A prototype implementation demonstrates the applicability of the proposed approach.

Original language	English
Title of host publication	Design Automation Conference (DAC)
Number of pages	6
Publication status	Published - 2020

Fields of science

102 Computer Sciences
202 Electrical Engineering, Electronics, Information Engineering

JKU Focus areas

Digital Transformation

Cite this

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title = "Verification for Field-coupled Nanocomputing Circuits",

abstract = "With the decline of Moore's Law, several post - CMOS technologies are currently under heavy consideration. Promising candidates can be found in the class of Field-coupled Nanocomputing (FCN) devices as they allow for highest processing performance with tremendously low energy dissipation. With upcoming design automation in this domain, the need for formal verification approaches arises. Unfortunately, FCN circuits come with certain domain-specific properties that render conventional methods for the verification non-applicable. In this paper, we investigate this issue and propose a verification approach for FCN circuits that addresses this problem. For the first time, this provides researchers and engineers with an automatic method that allows them to check whether an obtained FCN circuit design indeed implements the given / desired function. A prototype implementation demonstrates the applicability of the proposed approach.",

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year = "2020",

language = "English",

booktitle = "Design Automation Conference (DAC)",

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T1 - Verification for Field-coupled Nanocomputing Circuits

AU - Walter, Marcel

AU - Wille, Robert

AU - Torres, Frank Sill

AU - Große, Daniel

AU - Drechsler, Rolf

PY - 2020

Y1 - 2020

N2 - With the decline of Moore's Law, several post - CMOS technologies are currently under heavy consideration. Promising candidates can be found in the class of Field-coupled Nanocomputing (FCN) devices as they allow for highest processing performance with tremendously low energy dissipation. With upcoming design automation in this domain, the need for formal verification approaches arises. Unfortunately, FCN circuits come with certain domain-specific properties that render conventional methods for the verification non-applicable. In this paper, we investigate this issue and propose a verification approach for FCN circuits that addresses this problem. For the first time, this provides researchers and engineers with an automatic method that allows them to check whether an obtained FCN circuit design indeed implements the given / desired function. A prototype implementation demonstrates the applicability of the proposed approach.

AB - With the decline of Moore's Law, several post - CMOS technologies are currently under heavy consideration. Promising candidates can be found in the class of Field-coupled Nanocomputing (FCN) devices as they allow for highest processing performance with tremendously low energy dissipation. With upcoming design automation in this domain, the need for formal verification approaches arises. Unfortunately, FCN circuits come with certain domain-specific properties that render conventional methods for the verification non-applicable. In this paper, we investigate this issue and propose a verification approach for FCN circuits that addresses this problem. For the first time, this provides researchers and engineers with an automatic method that allows them to check whether an obtained FCN circuit design indeed implements the given / desired function. A prototype implementation demonstrates the applicability of the proposed approach.

M3 - Conference proceedings

BT - Design Automation Conference (DAC)

ER -