Approximate computing circuits are considered as a promising solution to reduce the power consumption in embedded data processing. This paper proposes an FPGA implementation for an approximate multiplier based on inexact adder circuits. The performance of the proposed multiplier is evaluated by comparing the power consumption, the accuracy of computation, and the time delay with those of an approximate multiplier based on exact adder presented in literature. Results reports a power saving up to 17.39% with an improvement in time delay by 13.49%, at cost of less than 5% of accuracy loss. \ua9 2017 IEEE
With the continuous development of integrated circuit manufacturing processes, the issue of power co...
A new approximate adder is proposed, which is suitable for FPGA- and ASIC-based implementations. Her...
This paper presents a delay- and energy-efficient approximate adder design exploiting an effective c...
Computation accuracy can be adequately tuned on the specific application requirements in order to re...
Abstract—Power dissipation has become a significant concern for integrated circuit design in nanomet...
Approximate Arithmetic is a new design paradigm that is being used in many applications which are to...
Multimedia and image processing applications, may tolerate errors in calculations but still generate...
CMOS scaling has reached to the level, where process variation has become significant problem hinder...
International audienceIn the last decade, Approximate Computing (AxC) has been extensively employed ...
Approximate computing forms a promising design alternative for inherently error resilient applicatio...
For a variety of different applications, including processing of image, expert systems, the smart th...
In this paper, we propose a methodology for designing low error efficient approximate adders for FPG...
Low power consumption is the necessity for the integrated circuit design in CMOS technology of nanom...
Abstract — Approximate computing has recently emerged as a promising approach to energy-efficient de...
In this paper, we propose a methodology for designing low error efficient approximate adders for FPG...
With the continuous development of integrated circuit manufacturing processes, the issue of power co...
A new approximate adder is proposed, which is suitable for FPGA- and ASIC-based implementations. Her...
This paper presents a delay- and energy-efficient approximate adder design exploiting an effective c...
Computation accuracy can be adequately tuned on the specific application requirements in order to re...
Abstract—Power dissipation has become a significant concern for integrated circuit design in nanomet...
Approximate Arithmetic is a new design paradigm that is being used in many applications which are to...
Multimedia and image processing applications, may tolerate errors in calculations but still generate...
CMOS scaling has reached to the level, where process variation has become significant problem hinder...
International audienceIn the last decade, Approximate Computing (AxC) has been extensively employed ...
Approximate computing forms a promising design alternative for inherently error resilient applicatio...
For a variety of different applications, including processing of image, expert systems, the smart th...
In this paper, we propose a methodology for designing low error efficient approximate adders for FPG...
Low power consumption is the necessity for the integrated circuit design in CMOS technology of nanom...
Abstract — Approximate computing has recently emerged as a promising approach to energy-efficient de...
In this paper, we propose a methodology for designing low error efficient approximate adders for FPG...
With the continuous development of integrated circuit manufacturing processes, the issue of power co...
A new approximate adder is proposed, which is suitable for FPGA- and ASIC-based implementations. Her...
This paper presents a delay- and energy-efficient approximate adder design exploiting an effective c...