Your search keyword '"Siozios, Kostas"' showing total 3 results

1. Variability-Aware Approximate Circuit Synthesis via Genetic Optimization.

Author

Balaskas, Konstantinos, Klemme, Florian, Zervakis, Georgios, Siozios, Kostas, Amrouch, Hussam, and Henkel, Jorg

Subjects

NANOELECTROMECHANICAL systems, TRANSISTORS, COMPLEMENTARY metal oxide semiconductors

Abstract

One of the major barriers that CMOS devices face at nanometer scale is increasing parameter variation due to manufacturing imperfections. Process variations severely inhibit the reliable operation of circuits, as the operational frequency at the nominal process corner is insufficient to suppress timing violations across the entire variability spectrum. To avoid variability-induced timing errors, previous efforts impose pessimistic and performance-degrading timing guardbands atop the operating frequency. In this work, we employ approximate computing principles and propose a circuit-agnostic automated framework for generating variability-aware approximate circuits that eliminate process-induced timing guardbands. Variability effects are accurately portrayed with the creation of variation-aware standard cell libraries, fully compatible with standard EDA tools. The underlying transistors are fully calibrated against industrial measurements from Intel 14nm FinFET in which both electrical characteristics of transistors and variability effects are accurately captured. In this work, we explore the design space of approximate variability-aware designs to automatically generate circuits of reduced variability and increased performance without the need for timing guardbands. Experimental results show that by introducing negligible functional error of merely $\boldsymbol {5.3 \times 10^{-3}}$ , our variability-aware approximate circuits can be reliably operated under process variations without sacrificing the application performance. [ABSTRACT FROM AUTHOR]

Published

2022

2. Automated Design Approximation to Overcome Circuit Aging.

Author

Balaskas, Konstantinos, Zervakis, Georgios, Amrouch, Hussam, Henkel, Jorg, and Siozios, Kostas

Subjects

IMAGE processing, TIMING circuits, LOGIC design, DETERIORATION of materials, TRANSISTORS, LOGIC circuits

Abstract

Transistor aging phenomena manifest themselves as degradations in the main electrical characteristics of transistors. Over time, they result in a significant increase of cell propagation delay, leading to errors due to timing violations, since the operating frequency becomes unsustainable as the circuit ages. Conventional techniques employ timing guardbands to mitigate aging-induced delay increase, which leads to considerable performance losses from the beginning of the circuit’s lifetime. Leveraging the inherent error resilience of a vast number of application domains, approximate computing was recently introduced as an aging mitigation mechanism. In this work, we present the first automated framework for generating aging-aware approximate circuits. Our framework, by applying directed gate-level netlist approximation, induces a small functional error and recovers the delay degradation due to aging. As a result, our optimized circuits eliminate aging-induced timing errors. Experimental evaluation over a variety of arithmetic circuits and image processing benchmarks demonstrates that for an average error of merely $5\times 10^{-3}$ , our framework completely eliminates aging-induced timing guardbands. Compared to the respective baseline circuits without timing guardbands (i.e., iso-performance evaluation), the error of the circuits generated by our framework is $1208\times $ smaller. [ABSTRACT FROM AUTHOR]

Published

2021

3. GENESIS: Parallel Application Placement onto Reconfigurable Architectures (Invited for the Special Issue on Runtime Management).

Author

DIAMANTOPOULOS, DIONYSIOS, SIOZIOS, KOSTAS, XYDIS, SOTIRIOS, and SOUDRIS, DIMITRIOS

Subjects

RUN time systems (Computer science), PARALLEL computers, COMPUTER architecture, GENETIC algorithms, MULTICORE processors

Abstract

Placement is though as the most time-consuming processes in physical implementation flows for reconfigurable architectures, while it highly affects the quality of derived application implementation, as it has impact on the maximum operating frequency. Throughout this article, we propose a novel placer, based on genetic algorithm, targeting to FPGAs. Rather than relevant approaches, which are executed sequentially, the new placer exhibits inherent parallelism, which can benefit from multicore processors. Experimental results prove the effectiveness of this solution, as it achieves average reduction of execution runtime and application's delay by 67× and 16%, respectively. [ABSTRACT FROM AUTHOR]

Published

2015