Gaurav Trivedi scite author profile

The concept of approximate computing, that is, to sacrifice computation quality for computation efforts, has recently emerged as a promising design approach. Over the past decade, several research works have explored approximate computing at both the software level and hardware level of abstraction with encouraging results. At the hardware level of abstraction, adders (being the fundamental and most widely used data operators in digital systems) have attracted a significant attention for approximation. In this article, we first explain briefly the need/significance of approximate adders. We then propose four Approximate Full Adders (AFAs) for high-performance energy-efficient approximate computing. The key design objective behind the proposed AFAs is to curtail the length of carry propagation subjected to minimal error rate. Next, we exploit one of the proposed AFAs (optimal one) to construct an N -bit approximate adder that hereinafter is referred as “ApproxADD.” An emergent property of ApproxADD is that carries do not propagate in it, and, consequently, it provides bit-width-aware constant delay ( O (1)). ApproxADD also provides improvement in dynamic power consumption by 46.31% and in area by 28.57% w.r.t. Ripple Carry Adder (RCA), which exhibits the lowest power and area. Although ApproxADD provides a significant improvement in delay, power, and area, it may not be preferred for some of the error-resilient applications because its: (i) Error Distance (ED) is too high; and (ii) Error Rate (ER) increases rapidly with bit-width ( N ). To improve ED and ER, we exploit the concept of carry-lifetime and Error Detection and Correction logic, respectively. In this way, we introduce two more (improved) versions of ApproxADD--ApproxADD υ 1 and ApproxADD. We call these as ApproxADD υ 1 and ApproxADD υ 2 with existing approximate adders based on conventional design metrics and approximate computing design metrics. Furthermore, to inspect effectiveness of the proposed approach in real-life applications, we demonstrate image compression and decompression by replacing the conventional addition operations in Discrete Cosine Transform (DCT) and Inverse Discrete Cosine Transform (IDCT) modules with ApproxADD υ 2.

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Regioselective total synthesis of (±) Neorautane, (±) Neorautanin and their analogs. Microwave mediated synthesis of 2H-chromenes from propargyl phenyl ethers

Katoch

Murugesh

Trivedi

1997

Tetrahedron

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A Security Framework for NoC Using Authenticated Encryption and Session Keys

Kapoor

Rao

Arshi

et al. 2013

Circuits Syst Signal Process

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Gaurav Trivedi

Cycloaddition of oxidopyrylium species in organic synthesis

Copper nanoparticles in ionic liquids: Recyclable and efficient catalytic system for 1,3-dipolar cycloaddition reaction

Analysis and Design of Adders for Approximate Computing

Regioselective total synthesis of (±) Neorautane, (±) Neorautanin and their analogs. Microwave mediated synthesis of 2H-chromenes from propargyl phenyl ethers

A Security Framework for NoC Using Authenticated Encryption and Session Keys

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