NVL-04.an Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator
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An Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator AIM: The main aim of the project is to design “ An Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator ”. (AB!RA"!# Complex arithmetic operations are widely used in Digital Signal Processing (DSP applications. !n this wor"# we focus on optimi$ing the design of the fused %dd& 'ultiply (%' operator for increasing performance. Te chni)ues to i mplement the direct recoding of the sum of two num*ers in its 'odified +ooth ('+ form. a structured and efficient recoding techni)ue and explore three different schemes *y incorporating them in % ' designs the % ' designs which use existing recoding schemes# the proposed techni)ue yields considera*le reductions in terms of critical delay# hardware complexity and power consumption of the % ' unit. $roposed Architecture: . Ad%antage: or optimi$ing the design of the used&%dd 'ultiply (%' operator# proposed a structured techni)ue for the direct recoding of the sum of two num*ers to its '+ ('odi fied +ooth form. ,xplore three alternati -e designs of the propose d S-MB (sum 'odified +ooth recorder and compare them to the existing ones and. The proposed recoding schemes# when they are incorporated in % ' designs# yield consi dera* le perfor mance impro-eme nts in comp arison with the most eff icien t recoding schemes
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Transcript of NVL-04.an Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator
An Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator
An Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator
AIM:
The main aim of the project is to design An Optimized Modified Booth Recoder for Efficient Design of the Add-Multiply Operator.
(ABSTRACT)
Complex arithmetic operations are widely used in Digital Signal Processing (DSP) applications. In this work, we focus on optimizing the design of the fused Add-Multiply (FAM) operator for increasing performance. Techniques to implement the direct recoding of the sum of two numbers in its Modified Booth (MB) form. a structured and efficient recoding technique and explore three different schemes
by incorporating them in FAM designs the FAM designs which use existing recoding schemes, the proposed technique yields considerable reductions in terms of critical delay, hardware complexity and power consumption of the FAM unit.
Proposed Architecture:
.
Advantage:
For optimizing the design of the Fused-Add Multiply (FAM) operator, proposed a structured technique for the direct recoding of the sum of two numbers to its MB (Modified Booth) form. Explore three alternative designs of the proposed S-MB (sum Modified Booth) recorder and compare them to the existing ones and. The proposed recoding schemes, when they are incorporated in FAM designs, yield considerable performance improvements in comparison with the most efficient recoding schemes
BLOCK DIAGRAM:
AM operator (a) conventional design fused design with direct recoding of
Recoding scheme of level of basic recoding cellTOOLS: hspice_vA-2008.03, t-spice
REFERENCE: [1] A. Amaricai, M. Vladutiu, and O. Boncalo, Design issues and implementations for floating-point divide-add fused, IEEE Trans. Circuits Syst. IIExp. Briefs, vol. 57, no. 4, pp. 295299, Apr. 2010.
[2] E. E. Swartzlander and H. H. M. Saleh, FFT implementation with fused floating-point operations, IEEE Trans. Comput., vol. 61, no. 2, pp. 284288, Feb. 2012.
[3] J. J. F. Cavanagh,Digital Computer Arithmetic. NewYork:McGraw- Hill, 1984.
[4] S. Nikolaidis, E. Karaolis, and E. D. Kyriakis-Bitzaros, Estimation of
signal transition activity in FIR filters implemented by a MAC architecture,
IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst., vol.19, no. 1, pp. 164169, Jan. 2000.
[5] O. Kwon, K. Nowka, and E. E. Swartzlander, A 16-bit by 16-bitMAC
design using fast 5: 3 compressor cells, J. VLSI Signal Process. Syst.,
vol. 31, no. 2, pp. 7789, Jun. 2002.
