Digital Signal Processing

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A Novel Design of Error-Tolerant Adder for Low-Power High-Speed DSP Applications


Affiliations
1 VLSI Design, Anna University of Technology, Coimbatore, India
2 Department of ECE, Anna University of Technology, Coimbatore, India
     

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In this paper a low power structure called Error Tolerant Adder is proposed. By adopting an emerging concept in VLSI design and test, error tolerance (ET), a novel error-tolerant adder (ETA) is proposed. The ETA is able to ease the strict restriction on accuracy, and at the same time achieve tremendous improvements in both the power consumption and speed performance and Area of chip. When compared to its conventional adder, the proposed ETA is able to attain more than 65% improvement in the Power-Delay Product (PDP). One important potential application of the proposed ETA is in digital signal processing systems that can tolerate certain amount of errors.

Keywords

Adders, Digital Signal Processing (DSP), Error Tolerance, High-Speed Integrated Circuits, Low-Power Design, VLSI.
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  • A Novel Design of Error-Tolerant Adder for Low-Power High-Speed DSP Applications

Abstract Views: 519  |  PDF Views: 2

Authors

Sriram Komanduri
VLSI Design, Anna University of Technology, Coimbatore, India
Bhagath Pyda
VLSI Design, Anna University of Technology, Coimbatore, India
S. Saravana Kumar
Department of ECE, Anna University of Technology, Coimbatore, India

Abstract


In this paper a low power structure called Error Tolerant Adder is proposed. By adopting an emerging concept in VLSI design and test, error tolerance (ET), a novel error-tolerant adder (ETA) is proposed. The ETA is able to ease the strict restriction on accuracy, and at the same time achieve tremendous improvements in both the power consumption and speed performance and Area of chip. When compared to its conventional adder, the proposed ETA is able to attain more than 65% improvement in the Power-Delay Product (PDP). One important potential application of the proposed ETA is in digital signal processing systems that can tolerate certain amount of errors.

Keywords


Adders, Digital Signal Processing (DSP), Error Tolerance, High-Speed Integrated Circuits, Low-Power Design, VLSI.