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Owing to recent challenges of CMOS manufacturing and power consumption in silicon technologies among alternative technologies, Nanomagnetic logic (NML) is one of the most promising technologies, so it was selected for this study. NML is non-volatile with ultra-low power dissipation that operates at room temperature. This paper aims to propose novel implementation of 2% and 4% multiplexers (MUXs) in NML technology.

The proposed multiplexers in NML technology are verified by HDL-based simulators. In addition, this study estimated area and power dissipation of the proposed design to compare and approve the promising improvements in comparison to other similar NML implementations.

The results show the remarkable improvements in terms of APDP term in comparison to the recent proposed MUXs in NML technology which are reported in Table 2. The proposed implementation of the MUX in NML is designed in three-dimensional layout to improve interconnection complexity which is an integration challenge. Also, by facilitating the routing signals and total wire length needed for clock signals, the negative impact of the power dissipated in clock wires is improved.

These findings would appeal to a broad audience, such as the readership of Microelectronics International Journal. The authors confirm that this work is original and has not been published elsewhere nor is it currently under consideration for publication elsewhere. All authors have approved the paper and agreed with submission to Microelectronics International Journal. The authors have read and have abided by the statement of ethical standards for manuscripts submitted to Microelectronics International Journal. The authors have no conflict of interest to declare.

The high demand for fast, energy-efficient, compact computational blocks in digital electronics has led the researchers to use approximate computing in applications where inaccuracy of outputs is tolerable. The purpose of this paper is to present two ultra-high-speed current-mode approximate full adders (FA) by using carbon nanotube field-effect transistors.

Instead of using threshold detectors, which are common elements in current-mode logic, diodes are used to stabilize voltage. Zener diodes and ultra-low-power diodes are used within the first and second proposed designs, respectively. This innovation eliminates threshold detectors from critical path and makes it shorter. Then, the new adders are employed in the image processing application of Laplace filter, which detects edges in an image.

Simulation results demonstrate very high-speed operation for the first and second proposed designs, which are, respectively, 44.7 per cent and 21.6 per cent faster than the next high-speed adder cell. In addition, they make a reasonable compromise between power-delay product (PDP) and other important evaluating factors in the context of approximate computing. They have very few transistors and very low total error distance. In addition, they do not propagate error to higher bit positions by generating output carry correctly. According to the investigations, up to four inexact FA can be used in the Laplace filter computations without a significant image quality loss. The employment of the first and second proposed designs results in 42.4 per cent and 32.2 per cent PDP reduction compared to when no approximate FA are used in an 8-bit ripple adder.

Two new current-mode inexact FA are presented. They use diodes as voltage regulators to design current-mode approximate full-adders with very short critical path for the first time.