Inexact (or approximate) computing is an attractive paradigm for digital processing at nanometric scales. Inexact computing is particularly interesting for computer arithmetic designs. This paper deals with the analysis and design of two new approximate 4-2 compressors for utilization in a multiplier. These designs rely on different features of compression, such that imprecision in computation (as measured by the error rate and the so-called normalized error distance) can be met with respect to circuit-based figures of merit of a design (number of transistors, delay and power consumption). Four different schemes for utilizing the proposed approximate compressors are proposed and analyzed for a Wallace multiplier. Extensive simulation result...
In the last decade, the need for efficiency in computing has motivated the coming forth of new devic...
We propose a high-speed, energy-efficient approximation multiplier. The method is to round the coeff...
In this paper we propose an energy-efficient approximate multiplier which uses a new approximate 4-2...
Inexact (or approximate) computing is an attractive paradigm for digital processing at nanometric sc...
At nanometric scales, approximate computing is an attractive prototype used for digital processing. ...
Multiplier, as a key role in many different applications, is a time-consuming, energy-intensive comp...
Approximate computing is a promising approach for reducing power consumption and design complexity i...
Abstract — Approximate computing is best suited for error resilient applications, such as signal pro...
Approximate computing is an emerging trend in digital design that trades off the requirement of exac...
Approximate computing is an attractive technique to gain substantial improvement in the area, speed,...
Low power consumption is the necessity for the integrated circuit design in CMOS technology of nanom...
Approximate computing is a popular field where accuracy is traded with energy. It can benefit applic...
Abstract — Approximate circuit design is an innovative paradigm for error-resilient image and signal...
Multimedia and image processing applications, may tolerate errors in calculations but still generate...
An application that can produce a useful result despite some level of computational error is said to...
In the last decade, the need for efficiency in computing has motivated the coming forth of new devic...
We propose a high-speed, energy-efficient approximation multiplier. The method is to round the coeff...
In this paper we propose an energy-efficient approximate multiplier which uses a new approximate 4-2...
Inexact (or approximate) computing is an attractive paradigm for digital processing at nanometric sc...
At nanometric scales, approximate computing is an attractive prototype used for digital processing. ...
Multiplier, as a key role in many different applications, is a time-consuming, energy-intensive comp...
Approximate computing is a promising approach for reducing power consumption and design complexity i...
Abstract — Approximate computing is best suited for error resilient applications, such as signal pro...
Approximate computing is an emerging trend in digital design that trades off the requirement of exac...
Approximate computing is an attractive technique to gain substantial improvement in the area, speed,...
Low power consumption is the necessity for the integrated circuit design in CMOS technology of nanom...
Approximate computing is a popular field where accuracy is traded with energy. It can benefit applic...
Abstract — Approximate circuit design is an innovative paradigm for error-resilient image and signal...
Multimedia and image processing applications, may tolerate errors in calculations but still generate...
An application that can produce a useful result despite some level of computational error is said to...
In the last decade, the need for efficiency in computing has motivated the coming forth of new devic...
We propose a high-speed, energy-efficient approximation multiplier. The method is to round the coeff...
In this paper we propose an energy-efficient approximate multiplier which uses a new approximate 4-2...