Abstract
Error resilient applications benefit from the use of approximate computing techniques that enhance electrical performances while allowing a deviation from the exact result. Many operations in signal processing require the square of a signal. Despite the fact that the squaring operation can be regarded as a special multiplication case, it is often preferable to develop independent squaring circuits to exploit possible architectural symmetries. This paper proposes novel approximate binary squarers, obtained by recursively exploiting 4-bit approximate multipliers and squarers. The final designs cover a wide range of computing precision, providing the user with multiple choices of different cost vs. accuracy trade-offs. The proposed circuits, as well as competitive designs, are synthesized targeting a 14 nm FinFET technology to determine the electrical characteristics. It is demonstrated that the proposed squarers outperform the state-of-the-art in terms of power vs. precision. Compared to the exact 8-bit squarer, the least dissipative proposed design reduces silicon area by 76%, power consumption by 71%, and critical delay by 72%. The same circuit dissipates 2.4% less power than the least dissipative design found in literature, while providing 34% more accurate results. The behavior of the considered designs is also tested in common error resilient applications, like signal demodulation and image processing.
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