A Bit-Width Optimization Methodology for Polynomial-Based Function Evaluation

A Bit-Width Optimization Methodology for Polynomial-Based Function Evaluation

We present an automated bit-width optimization methodology for polynomial-based hardware function evaluation. Due to the analytical nature of the approach, overflow protection and precision accurate to one unit in the last place (ulp) can be guaranteed. A range analysis technique based on computing...

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Veröffentlicht in:IEEE transactions on computers 2007-04, Vol.56 (4), p.567-571
Hauptverfasser: Lee, Dong-U, Villasenor, John D.
Format: Artikel
Sprache:eng
Schlagworte:
Computation
Computer arithmetic
Derivatives
elementary function approximation
Estimation
field programmable gate arrays
finite wordlength effects
Hardware
Indexes
Mathematical analysis
Mathematical models
Methodology
minimax approximation and algorithms
Optimization
Quantization (signal)
Resource management
Simulated annealing
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Zusammenfassung:We present an automated bit-width optimization methodology for polynomial-based hardware function evaluation. Due to the analytical nature of the approach, overflow protection and precision accurate to one unit in the last place (ulp) can be guaranteed. A range analysis technique based on computing the root of the derivative of a signal is utilized to determine the minimal number of integer bits. Fractional bit requirements are established using an analytical error expression derived from the functions that occur along the data path. Global fractional bit optimization across multiple computation stages is performed using simulated annealing and circuit area estimation functions
ISSN:0018-9340
1557-9956
DOI:10.1109/TC.2007.1013