W.E. Alexander scite author profile

We present a performance analysis framework that efficiently generates and analyzes hardware designs for computationally intensive signal processing applications. Our framework synthesizes designs from a high level of abstraction into well-constructed and recognizable hardware structures that perform well in terms of area, throughput and power dissipation. Cost functions provided by our framework allow the user to reduce the design space to a set of efficient hardware implementations that meet performance constraints. We utilize our framework to estimate hardware performance using a set of pre-synthesized mathematical cores which expedites the synthesis process by approximately 14 fold. This reduces the architectural generation and hardware synthesis process from days to several hours for complex designs. Our work aims at performing hardware optimizations at the architectural and arithmetic levels, relieving the user from manually describing the designs at the register transfer level and iteratively varying the hardware structures. We illustrate the efficiency and accuracy of our framework by generating finite impulse response filter structures used in several signal processing applications such as adaptive equalizers and quadrature mirror filters. The results show that hardware filter structures generated by our framework can achieve, on average, a 3 fold increase in power efficiency when compared to manually constructed designs.

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An efficient VLSI implementation for the 1D convolutional discrete wavelet transform

Hourani

Dalal

Davis

et al. 2008

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W.E. Alexander

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An efficient VLSI implementation for the 1D convolutional discrete wavelet transform

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