Result Details

Approximating Complex Arithmetic Circuits with Formal Error Guarantees: 32-bit Multipliers Accomplished

ČEŠKA, M.; MATYÁŠ, J.; MRÁZEK, V.; VAŠÍČEK, Z.; SEKANINA, L.; VOJNAR, T. Approximating Complex Arithmetic Circuits with Formal Error Guarantees: 32-bit Multipliers Accomplished. In Proceedings of 36th IEEE/ACM International Conference On Computer Aided Design (ICCAD). Irvine, CA: Institute of Electrical and Electronics Engineers, 2017. p. 416-423. ISBN: 978-1-5386-3093-8.

Type

conference paper

Language

English

Authors

Češka Milan, doc. RNDr., Ph.D., DITS (FIT)
Matyáš Jiří, Ing., Ph.D.
Mrázek Vojtěch, Ing., Ph.D., DCSY (FIT)
Vašíček Zdeněk, doc. Ing., Ph.D., DCSY (FIT)
Sekanina Lukáš, prof. Ing., Ph.D., DCSY (FIT)
Vojnar Tomáš, prof. Ing., Ph.D., DITS (FIT)

Abstract

We present a novel method allowing one to approximate complex arithmetic circuits with formal guarantees on the approximation error. The method integrates in a unique way formal techniques for approximate equivalence checking into a search-based circuit optimisation algorithm. The key idea of our approach is to employ a novel search strategy that drives the search towards promptly verifiable approximate circuits. The method was implemented within the ABC tool and extensively evaluated on functional approximation of multipliers (with up to 32-bit operands) and adders (with up to 128-bit operands). Within a few hours, we constructed a high-quality Pareto set of 32-bit multipliers providing trade-offs between the circuit error and size. This is for the first time when such complex
approximate circuits with formal error guarantees have been derived, which demonstrates an outstanding performance and scalability of our approach compared with existing methods that have either been applied to the approximation of multipliers limited to 8-bit operands or statistical testing has been used only. Our approach thus significantly improves capabilities of the existing methods and paves a way towards an automated design process of provably-correct circuit approximations.

Keywords

approximate computing, logical synthesis, genetic programming, formal methods

Published

2017

Pages

416–423

Proceedings

Proceedings of 36th IEEE/ACM International Conference On Computer Aided Design (ICCAD)

Conference

IEEE/ACM International Conference On Computer-Aided Design

ISBN

978-1-5386-3093-8

Publisher

Institute of Electrical and Electronics Engineers

Place

Irvine, CA

DOI

10.1109/ICCAD.2017.8203807

UT WoS

000424863100055

EID Scopus

2-s2.0-85043523353

BibTeX

@inproceedings{BUT144430,
  author="Milan {Češka} and Jiří {Matyáš} and Vojtěch {Mrázek} and Zdeněk {Vašíček} and Lukáš {Sekanina} and Tomáš {Vojnar}",
  title="Approximating Complex Arithmetic Circuits with Formal Error Guarantees: 32-bit Multipliers Accomplished",
  booktitle="Proceedings of 36th IEEE/ACM International Conference On Computer Aided Design (ICCAD)",
  year="2017",
  pages="416--423",
  publisher="Institute of Electrical and Electronics Engineers",
  address="Irvine, CA",
  doi="10.1109/ICCAD.2017.8203807",
  isbn="978-1-5386-3093-8",
  url="https://www.fit.vut.cz/research/publication/11420/"
}

Files

pdf 06A_2.pdf 1 MB

Projects

IT4Innovations excellence in science, MŠMT, Národní program udržitelnosti II, LQ1602, start: 2016-01-01, end: 2020-12-31, completed
Relaxed equivalence checking for approximate computing, GACR, Standardní projekty, GA16-17538S, start: 2016-01-01, end: 2018-12-31, completed

Research groups

Evolvable Hardware Research Group (RG EHW)
Automated Analysis and Verification Research Group - VeriFIT (RG VERIFIT)

Departments

Department of Computer Systems (DCSY)
Department of Intelligent Systems (DITS)