Reduced Precision Redundancy (RPR) is a popular Approximate Computing technique, in which a circuit operated in Voltage Over-Scaling (VOS) is paired to a reduced-bitwidth and faster replica so that VOS-induced timing errors are partially recovered by the replica, and their impact is mitigated. Previous works have provided various examples of effective implementations of RPR, which however suffer from three limitations: first, these circuits are designed using ad-hoc procedures, and no generalization is provided; second, error impact analysis is carried out statistically, thus neglecting issues like non-elementary data distribution and temporal correlation. Last, only dynamic power was considered in the optimization. In this work we propose ...
Approximate computing is an emerging computing paradigm that offers improved power consumption by re...
Semiconductor feature size has been shrinking significantly in the past decades. This decreasing tre...
In this paper, we propose a dependable low-control multiplier configuration by receiving algorithmic...
We design the fixed-width RPR with error compensation circuit via analyzing of probability and stati...
Technology scaling poses an increasing challenge to the reliability of digital circuits. Hardware re...
Many modern workloads such as multimedia, recognition, mining, search, vision, etc. possess the char...
textRecent interest in approximate computation is driven by its potential to achieve large energy sa...
The suggested ANT architecture can satisfy the need for high precision, low power consumption, and a...
Leveraging the inherent error tolerance of a vast number of application domains that are rapidly gro...
Energy-efficiency is a critical concern for many systems, ranging from Internet of things objects an...
Approximate computing (AC) has been predominantly recommended for implementation in error-tolerant a...
International audienceFor arithmetic circuits, Reduced-Precision Redundancy (RPR) is considered to b...
International audienceVoltage scaling has been used as a prominent technique to improve energy effic...
It has been a while since Approximate Computing (AxC) is applied systematically at various abstracti...
Inexact hardware design techniques have become popular in error-tolerant systems, where energy effic...
Approximate computing is an emerging computing paradigm that offers improved power consumption by re...
Semiconductor feature size has been shrinking significantly in the past decades. This decreasing tre...
In this paper, we propose a dependable low-control multiplier configuration by receiving algorithmic...
We design the fixed-width RPR with error compensation circuit via analyzing of probability and stati...
Technology scaling poses an increasing challenge to the reliability of digital circuits. Hardware re...
Many modern workloads such as multimedia, recognition, mining, search, vision, etc. possess the char...
textRecent interest in approximate computation is driven by its potential to achieve large energy sa...
The suggested ANT architecture can satisfy the need for high precision, low power consumption, and a...
Leveraging the inherent error tolerance of a vast number of application domains that are rapidly gro...
Energy-efficiency is a critical concern for many systems, ranging from Internet of things objects an...
Approximate computing (AC) has been predominantly recommended for implementation in error-tolerant a...
International audienceFor arithmetic circuits, Reduced-Precision Redundancy (RPR) is considered to b...
International audienceVoltage scaling has been used as a prominent technique to improve energy effic...
It has been a while since Approximate Computing (AxC) is applied systematically at various abstracti...
Inexact hardware design techniques have become popular in error-tolerant systems, where energy effic...
Approximate computing is an emerging computing paradigm that offers improved power consumption by re...
Semiconductor feature size has been shrinking significantly in the past decades. This decreasing tre...
In this paper, we propose a dependable low-control multiplier configuration by receiving algorithmic...