Quantum-dot cellular automata (QCA) is a novel nano-electronic technology. QCA has attracted wide attention due to its extremely small feature sizes at the molecular or even atomic scale and ultra-low power consumptio...
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Quantum-dot cellular automata (QCA) is a novel nano-electronic technology. QCA has attracted wide attention due to its extremely small feature sizes at the molecular or even atomic scale and ultra-low power consumption, making it a promising candidate to replace the complementary metal oxide semiconductor (CMOS) technology. Binary-coded Decimal (BCD) adders are widely used in industrial computing. In this brief, we propose two types of excess-3 code (XS-3) based BCD adders (XS-3DAs). We use ripple-carry adders (RCA) and parallel binary adders (PBA) to construct XS-3DAs in QCA Designer tool, respectively. The PBA-based XS-3DA is constructed with a new correction logic. 4-bit, 8-bit, and 16-bit XS-3DAs are constructed based on the two proposed XS-3DAs, respectively. Comparisons show that, with the increase of design scaling, the delay and area-delay product (ADP) of the PBA-based XS-3DAs can be significantly reduced in comparison with that of the RCA-based XS-3DAs. Compared with the 16-digit RCA-based XS-3DA, the cell count, area, delay and ADP of the proposed 16-digit PBA-based XS-3DA are reduced by 37.88%, 25.99%, 37.68% and 53.88%, respectively.
Decreasing power consumption is the leading challenge for very-large-scale-integrated (VLSI) designers. This paper introduces an innovative prototype for a power-efficient standard or a fully-adiabatic binary-coded-de...
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Decreasing power consumption is the leading challenge for very-large-scale-integrated (VLSI) designers. This paper introduces an innovative prototype for a power-efficient standard or a fully-adiabatic binary-coded-decimal (BCD) 8421 to excess-3 (XS-3) code converter. The proposed design is compared with traditional complementary metal oxide semiconductor (CMOS) as well as two popular fully adiabatic logic families: adiabatic dynamic CMOS logic (ADCL) and two phase clocked adiabatic static CMOS logic (2PASCL). This investigation was conducted at frequencies ranging from 100 to 900 MHz. The circuit employs 0.3 mu m CMOS technology, with channel length and width set at 0.3 mu m and 0.75 mu m, respectively. The power savings for the proposed logic at 500 MHz when compared to standard CMOS logic, ADCL, and 2PASCL are 54.54%, 28.57%, and 16.67%, respectively.
Quantum-dot cellular automata (QCA) based circuit designs are creating a surge in transistorless computational technologies. Due to its quasi-adiabatic switching resulting in extremely low leakage power dissipation as...
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Quantum-dot cellular automata (QCA) based circuit designs are creating a surge in transistorless computational technologies. Due to its quasi-adiabatic switching resulting in extremely low leakage power dissipation as there is no continuous path. These circuits also enjoy extremely high packaging density of the order of 10(12) devices/cm(2) because of its extremely scaled area of 18 nm x 18 nm along with very high 100 GHz frequency of operation. Further the loss of bit information could be abolished by reversible logic computing. This thereby realizes an energy efficient logic operations owing to bijective relation between inputs and outputs in reversible logic. This work investigates the code converter circuits which converts 4-bit binary code to excess-3 code and vice versa based on reversible QCA logic gates for the first time. Moreover an area efficient design for 4-bit binary to gray and vice-versa code converters also designed here. All these four code converter circuits are designed using reversible logic gate Feynman and Peres gates by deploying the QCA Designer and Designer-E tool v2.0.3. Finally the in depth performance estimation of the proposed circuits in terms of circuit complexity, quantum cost and energy dissipation are also presented here. Moreover, these QCA based circuits provide a strong evidence that reversible logic based QCA circuits can be efficiently deployed for these code converter circuits.
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