Approximate multipliers attract a large interest in the scientific literature that proposes several circuits built with approximate 4-2 compressors. Due to the large number of proposed solutions, the designer who wishes to use an approximate 4-2 compressor is faced with the problem of selecting the right topology. In this paper, we present a comprehensive survey and comparison of approximate 4-2 compressors previously proposed in literature. We present also a novel approximate compressor, so that a total of twelve different approximate 4-2 compressors are analyzed. The investigated circuits are employed to design 8 × 8 and 16 × 16 multipliers, implemented in 28nm CMOS technology. For each operand size we analyze two multiplier configurations, with different levels of approximations, both signed and unsigned. Our study highlights that there is no unique winning approximate compressor topology since the best solution depends on the required precision, on the signedness of the multiplier and on the considered error metric.
Approximate computing is an emerging trend in digital design that trades off the requirement of exact computation for improved speed and power performance. This paper proposes novel approximate compressors and an algorithm to exploit them for the design of efficient approximate multipliers. By using the proposed approach, we have synthesized approximate multipliers for several operand lengths using a 40-nm library. Comparison with previously presented approximated multipliers shows that the proposed circuits provide better power or speed for a target precision. Applications to image filtering and to adaptive least mean squares filtering are also presented in the paper.
A new sense-amplifier-based flip-flop is presented.
The output latch of the proposed circuit can be considered as
an hybrid solution between the standard NAND-based set/reset
latch and the NC-2MOS approach. The proposed flip-flop provides
ratioless design, reduced short-circuit power dissipation,
and glitch-free operation. The simulation results, obtained for a
0.25- m technology, show improvements in the clock-to-output
delay and the power dissipation with respect to the recently proposed
high-speed flip-flops. The new circuit has been successfully
employed in a high-speed direct digital frequency synthesizer
chip, highlighting the effectiveness of the proposed flip-flop in
high-speed standard cell-based applications
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