A Low-Power High-Speed Accuracy-Controllable Approximate Multiplier Design
DOI:
https://doi.org/10.70914/Keywords:
Xilinx-ISEAbstract
In CMOS-based application-specific integrated circuit (ASIC) designs, total power consumption is
dominated by dynamic power, where dynamic power consists of two major components, namely, switching
power and internal power. In this paper, we present a low-power design for a accuracy-controllable
multiplier. Multiplication is a key fundamental function for many error-tolerant applications. Approximate
multiplication is considered to be an efficient technique for trading off energy against performance and
accuracy. This paper proposes an accuracy-controllable multiplier whose final product is generated by a
carry-maskable adder. The proposed scheme can dynamically select the length of the carry propagation to
satisfy the accuracy requirements flexibly. The partial product tree of the multiplier is approximated by the
proposed tree compressor. An multiplier design is implemented by employing the carry maskable adder
and the compressor. Compared with a conventional multiplier, the proposed multiplier reduced power
consumption. The implementation, synthesis and simulation is executed and noted in the Xilinx-ISE in
verilog HDL language.
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