A Power-Efficient Single Layer Full Adder Design in Field-Coupled QCA Nanocomputing

As an emerging technology device, Quantum-dot cellular automata (QCA) may be a suitable substitute for traditional semiconductor transistor technology. Arithmetic logic unit in field-coupled QCA has been also studied extensively in recent year. In this paper, the new low-power Exclusive-OR gate is presented, which is mainly based on QCA cellular leveled format. This Exclusive-OR gate can be used to design various useful QCA circuits. By using this gate, we design and implement a novel full adder circuit with low dissipation. The circuit is designed using only 45 normal cells in a single layer without crossover. Compared with previous designs, both decimal adders achieve better performance in terms of latency and overall cost. The operation of the proposed circuit has been verified by QCADesigner version 2.0.3 and energy dissipation investigated by QCAPro tool. We also compared with previous designs in terms of power dissipation, cell-counts, area, latency and cost. The proposed full adder has the smallest area with less number of cells. And the total energy dissipation of our proposed full adder are only 0.05112 eV, 0.07454 eV and 0.10181 eV when tunneling energy levels are 0.5 Ek, 1 Ek and 1.5 Ek, respectively. The proposed single full adder also has the lowest total energy dissipation with a reduction of 20.94, 11.25 and 4.82% in 0.5 E_k, 1 E_k and 1.5 E_k tunneling energy levels, respectively when compared with the previous most power-efficient design.

     

Robust Coplanar Full Adder Based on Novel Inverter in Quantum Cellular Automata

Quantum dot cellular automata (QCA) is one of the nano-scale computing paradigms which promises high speed and ultra-low power consumption. Since the one-bit full adder is a fundamental building block of arithmetic circuits, designing an efficient QCA full adder cell is very imperative in this new technology. In this paper, we propose a QCA full adder using a new inverter gate which leads to reduced complexity and area occupation. The proposed layout is simulated by the QCA designer engines. We also provide a performance comparison of our proposed QCA full adder with the previous relevant designs. Furthermore, a detailed analysis of energy dissipation is performed which demonstrates the superiority of the proposed design in terms of the energy efficiency.

     

Quantum legitimacy of reversible gate and a new design of multiplier based on R gate

Quantum full adders play a key role in the design of quantum computers. The efficiency of a quantum adder directly determines the speed of the quantum computer, and its complexity is closely related to the difficulty and the cost of building a quantum computer. The existed full adder based on R gate is a great design but it is not suitable to construct a quantum multiplier. We show the quantum legitimacy of some common reversible gates, then use R gate to propose a new design of a quantum full adder. We utilize the new designed quantum full adder to optimize the quantum multiplier which is based on R gate. It is shown that the new designed one can be optimized by a local optimization rule so that it will have lower quantum cost than before.     

Modular Adder Designs Using Optimal Reversible and Fault Tolerant Gates in Field-Coupled QCA Nanocomputing

The challenges which the CMOS technology is facing toward the end of the technology roadmap calls for an investigation of various logical and technological solutions to CMOS at the nano scale. Two such paradigms which are considered in this paper are the reversible logic and the quantum-dot cellular automata (QCA) nanotechnology. Firstly, a new 3 × 3 reversible and universal gate, RG-QCA, is proposed and implemented in QCA technology using conventional 3-input majority voter based logic. Further the gate is optimized by using explicit interaction of cells and this optimized gate is then used to design an optimized modular full adder in QCA. Another configuration of RG-QCA gate, CRG-QCA, is then proposed which is a 4 × 4 gate and includes the fault tolerant characteristics and parity preserving nature. The proposed CRG-QCA gate is then tested to design a fault tolerant full adder circuit. Extensive comparisons of gate and adder circuits are drawn with the existing literature and it is envisaged that our proposed designs perform better and are cost efficient in QCA technology.     

Novel Efficient Circuit Design for Multilayer QCA RCA

The novel emerging technology, QCA technology, is a candidate for replacing CMOS technology. Full Adder (FA) circuits are also widely used circuits in arithmetic circuits design. In this paper, two new multilayer QCA architectures are presented: one-bit FA and 4-bit Ripple Carry Adder (RCA). The designed one-bit multilayer FA architecture is based on a new XOR gate architecture. The designed 4-bit multilayer QCA RCA is also developed based on the designed one-bit multilayer QCA FA. The functionality of the designed architectures are verified using QCADesigner tool. The results indicate that the designed architecture for 4-bit multilayer QCA RCA requires 5 clock phases, 125 QCA cells, and 0.17 μm² area. The comparison results confirm that the designed architectures provide improvements compared with other adder architectures in terms of cost, cell count, and area.

     

Design of Ultra-Efficient Reversible Gate Based 1-bit Full Adder in QCA with Power Dissipation Analysis

The difficulties which the CMOS technology is facing at the nano scale has led to the investigation of quantum-dot cellular automata (QCA) nanotechnology and reversible logic as an alternative to conventional CMOS technology. In this paper, these two paradigms have been combined. Firstly, a new 3 × 3 reversible gate, SSG-QCA, which is universal and multifunctional in nature, is proposed and implemented in QCA using conventional 3-input majority voter based logic. By using the concept of explicit interaction of cells, the proposed gate is further optimized and then used to design an ultra-efficient 1-bit full adder in QCA. The universal nature has been verified by designing all the logic gates from the proposed SSG-QCA gate whereas the multifunctional nature is verified by implementing all the 13 standard Boolean functions. The proposed 3 × 3 gate and adder designs are then extensively compared with the existing literature and it is observed that the proposed designs are ultra-efficient in terms of both area and cost in QCA technology. In addition to this energy dissipation analysis for different scenarios is also done on all the designs and it is observed that the proposed designs dissipate minimum energy thereby making them suitable for ultra-low power designs.

     

A New Coplanar Design of Multiplier Based on Nanoscale Quantum-Dot Cellular Automata

Quantum-dot cellular automata (QCA) nanotechnology is emerging as a replacement technique for maintaining increasing microprocessor performance and it yields small size, high speed, and low power consumption. On the other hand, a multiplier is a circuit that multiplies two binary values for performing sequential addition operations and accumulating the results. This type of circuit is the basic structural unit of many arithmetic logical units, digital signal processing, and communication system. The multiplier circuit contains some full adders that can perform add operations, so, it is very important that low-complexity full adders are used. Therefore, in this paper, a new 2 × 2 array multiplier circuit in QCA by employing an efficient structure of full adder is designed and implemented. This design is constructed using coplanar layouts and compared its performance with existing QCA multipliers. The operation and efficiency of the proposed structure have been confirmed using QCADesigner tool. The simulation results have demonstrated that the 2 × 2 multiplier leads to less cell count and area as the prime designing factors.

     

Designing a New 4:2 Compressor Using an Efficient Multi-Layer Full-Adder Based on Nanoscale Quantum-Dot Cellular Automata

Quantum-dot Cellular Automata (QCA) is novel prominent nanotechnology. It promises a substitution to Complementary Metal–Oxide–Semiconductor (CMOS) technology with a higher scale integration, smaller size, faster speed, higher switching frequency, and lower power consumption. It also causes digital circuits to be schematized with incredible velocity and density. The full adder, compressor, and multiplier circuits are the basic units in the QCA technology. Compressors are an important class of arithmetic circuits, and researchers can use quantum compressors in the structure of complex systems. In this paper, first, a novel three-input multi-layer full-adder in QCA technology is designed, and based on it, a new multi-layer 4:2 compressor is presented. The proposed QCA-based full-adder and compressor uses an XOR gate. The proposed design offers good performance regarding the delay, area size, and cell number comparing to the existing ones. Also, in this gate, the output signal is not enclosed, and we can use it easily. The accuracy of the suggested circuits has been assessed with the utilization of QCADesigner 2.0.3. The results show that the proposed 4:2 compressor architecture utilizes 75 cell and 1.25 clock phases, which are efficient than other designs.

     

Quaternary Quantum/Reversible Half-Adder,Full-Adder,Parallel Adder and Parallel Adder/Subtractor Circuits

Multiple valued quantum logic is a promising research area in quantum computing technology having several advantages over binary quantum logic. Adder circuits as well as subtractor circuits are the major components of various computational units in computers and other complex computational systems. In this paper, we propose a quaternary quantum reversible half-adder circuit using quaternary 1-qudit gates, 2-qudit Feynman and Muthukrishnan-Stroud gates. Then we propose a quaternary quantum reversible full adder and a quaternary quantum parallel adder circuit. In addition, we propose a quaternary quantum reversible parallel adder/subtractor circuit. The proposed designs are compared with existing designs and improvements in terms of hardware complexity, quantum cost, number of constant inputs and garbage outputs are reported.

     

Shannon Logic Based Novel QCA Full Adder Design with Energy Dissipation Analysis

Quantum-dot Cellular Automata (QCA) is an emerging nanotechnology to replace VLSI-CMOS digital circuits. Due to its attractive features such as low power consumption, ultra-high speed switching, high device density, several digital arithmetic circuits have been proposed. Adder circuit is the most prominent component used for arithmetic operations. All other arithmetic operation can be successively performed using adder circuits. This paper presents Shannon logic based QCA efficient full adder circuit for arithmetic operations. Shannon logic expression with control variables helps the designer to reduce hardware cost; using with minimum foot prints of the chip size. The mathematical models of the proposed adder are verified with the theoretical values. In addition, the energy dissipation losses of the proposed adder are carried out. The energy dissipation calculation is evaluated under the three separate tunneling energy levels, at temperature T = 2K.The proposed adder dissipates less power. QCAPro tool is used for estimating the energy dissipation. In this paper we proposed novel Shannon based adder for arithmetic calculations. This adder has been verified in different aspects like using Boolean algebra besides it power analysis has been calculated. In addition 1-bit full adder has been enhanced to propose 2-bit and 4-bit adder circuits.     

Design of Low-Complexity and High-Speed Coplanar Four-Bit Ripple Carry Adder in QCA Technology

Quantum-dot Cellular Automata (QCA) technology is a suitable technology to replace CMOS technology due to low-power consumption, high-speed and high-density devices. Full adder has an important role in the digital circuit design. This paper presents and evaluates a novel single-layer four-bit QCA Ripple Carry Adder (RCA) circuit. The developed four-bit QCA RCA circuit is based on novel QCA full adder circuit. The developed circuits are simulated using QCADesigner tool version 2.0.3. The simulation results show that the developed circuits have advantages in comparison with existing single-layer and multilayer circuits in terms of cell count, area occupation and circuit latency.     

Effective Designs of Reversible Vedic Multiplier

Power dissipation problem is one of the most challenging problems in designing conventional electronic circuits. One of the best approaches to overcome this problem is to design reversible circuits. Nowadays, reversible logic is considered as a new field of study that has various applications such as optical information processing, design of low power CMOS circuits, quantum computing, DNA computations, bioinformatics and nanotechnology. Due to the vulnerability of the digital circuits to different environmental factors, the design of circuits with error-detection capability is considered a necessity. Parity preserving technique is known as one of the most famous methods for providing error-detection ability. Multiplication operation is considered as one of the most important operations in computing systems, which can play a significant role in increasing the efficiency of such systems. In this paper, two efficient 4-bit reversible multipliers are proposed using the Vedic technique. The Vedic technique is able to increase the speed of multiplication operation by producing partial products and their sums simultaneously in a parallel manner. The first architecture lacks the parity preserving potential, while the second architecture has the ability parity preserving. Since a 4-bit Vedic multiplier includes 2-bit Vedic multipliers and 4-bit ripple carry adders (RCA), so in the first design, TG, PG and FG gates have been used to design an efficient 2-bit reversible Vedic multiplier, as well as PG gate and HNG block have been applied as a half-adder (HA) and full-adder (FA) in the 4-bit RCAs. Also, in the second design, 2-bit parity preserving reversible Vedic multiplier has been designed using FRG, DFG, ZCG and PPTG gates as well as ZCG and ZPLG blocks have been utilized as HA and FA in the 4-bit RCAs. Proposed designs are compared in terms of evaluation criteria of circuits such as gate count (GC), number of constant inputs (CI), number of garbage outputs (GO), quantum cost (QC), and hardware complexity. The results of the comparisons indicate that the proposed designs are more efficient compared to available counterparts.

     

Toward Efficient Design of Flip-flops in Quantum-Dot Cellular Automata with Power Dissipation Analysis

Quantum-dot cellular automata (QCA) is one of the emergent nano-technologies and a potential substitute for transistor based technologies. In this research, an efficient QCA based T, SR and JK flip-flops have been proposed. The proposed gates are implemented with multiplexer, three-input Majority gate and XOR gate. The circuit layouts are designed and verified using QCADesigner version 2.0.3. The simulation result reviles the excellence of the proposed design. The proposed T flip-flop archives 35% improvement in terms cell count. Similarly, the reported RS and JK flip-flop requires 43% and 50% less area respectively in comparison to the previous best single layer design. In addition, QCAPro tool has been used to estimate the power dissipation of all considered designs at different tunneling energy level.     

Design of Cost-Efficient QCA Reversible Circuits via Clock-Zone-Based Crossover

Nanotechnologies, remarkably Quantum-dot Cellular Automata (QCA), offer an attractive perspective for future computing technologies. In this paper, QCA is investigated as an implementation method for reversible logic. A novel Reversible Gate is developed using QCA technology. Performance of the proposed gate is verified using thirteen standard three variables Boolean functions, which demonstrate from 14.3% to 42.8% superiority in term of gate counts obtained with other reversible gates. Proposed reversible gate requires switching and leakage energy dissipation of 0.168 eV and 0.271 eV, respectively, at 1.5 E_k energy level. The proposed gate uses 146 cells occupying only 0.14 μ m² area and then used to design a full adder. We use a coplanar QCA crossover architecture in the designs that uses non-adjacent clock zones for the two crossing wires. These designs have been realized with QCADesigner.     

Optimization Approaches for Designing a Novel 4-Bit Reversible Comparator

Reversible logic is a new rapidly developed research field in recent years, which has been receiving much attention for calculating with minimizing the energy consumption. This paper constructs a 4×4 new reversible gate called ZRQ gate to build quantum adder and subtraction. Meanwhile, a novel 1-bit reversible comparator by using the proposed ZRQC module on the basis of ZRQ gate is proposed as the minimum number of reversible gates and quantum costs. In addition, this paper presents a novel 4-bit reversible comparator based on the 1-bit reversible comparator. One of the vital important for optimizing reversible logic is to design reversible logic circuits with the minimum number of parameters. The proposed reversible comparators in this paper can obtain superiority in terms of the number of reversible gates, input constants, garbage outputs, unit delays and quantum costs compared with the existed circuits. Finally, MATLAB simulation software is used to test and verify the correctness of the proposed 4-bit reversible comparator.     

Counters Designs with Minimum Number of Cells and Area in the Quantum-Dot Cellular Automata Technology

The quantum-dot cellular automata (QCA) were highly regarded due to its high operating frequency and significantly low power consumption. One of the most useful circuits in processors architecture is counter. This paper presents effective designs and arrangement of QCA based counter-circuits. In this study new counter circuits in QCA technology are designed and precise simulation are done using the QCADesigner. Three, four and five bits counters are proposed in this paper in QCA technology. A comparison is made between the past and recent designs to illustrate which method is better and more efficient in terms of area, complexity, number of cells, and delay. For example, the proposed three bit shift register has 174 quantum cells, 0.2μm² occupied area and three QCA clock cycles delay.

     

基于混沌计算的全加器实现

混沌计算是一种使用混沌单元实现基本逻辑门的新计算模式. 基于混沌计算的思想提出了实现全加器的新方法,通过设定不同的阀值及判断条件,使用一个混沌单元实现全加器. 与传统全加器的实现相比,降低了全加器结构上的复杂性,提供了实现上的灵活性. 最后,以Logistic映射为例给出了使用一个混沌单元实现全加器的方法. 关键词： 混沌 混沌计算 全加器     

Programmable magnetologic full adder

Logic performed with magnetic materials is expected to offer decisive advantages compared to transistor-based logic. Recently, we introduced a new concept to employ a single magnetoresistive element – the basic building block of magnetic random access memory (MRAM) – as a programmable logic gate where each of the four distinct initial states corresponds to one of the four elementary logic functions (N)AND and (N)OR. Utilizing the two key-properties inherent in magnetoresistive elements, namely the non-volatility of information and the programmability at run-time, we present here an efficient magnetologic design of a full adder, the most widely used logic block in computing. According to our estimates, it is competitive in speed even with the fastest transistor-based full adders proposed in the literature and superior with respect to power and area consumption. PACS 85.75.Ff; 85.75.Bb; 85.75.Dd     

Design of Novel Coplanar Counter Circuit in Quantum Dot Cellular Automata Technology

One of the emerging technology that can be used for replacing CMOS technology is Quantum-dot Cellular Automata (QCA) technology. Counter circuits are widely used circuits in the design of digital circuits. This paper presents and evaluates circuits for 2-, 3-, 4-, and 5-bit coplanar counter in the QCA technology. The designed QCA coplanar counter circuits are based on the modified D-Flip-Flop (D-FF) circuit that is designed in this paper. The designed QCA circuits are implemented and verified by using QCADesigner tool version 2.0.3. The results show that the designed circuits for 2-, 3-, 4-, and 5-bit coplanar counter contain 44 (0.03 μm²), 93 (0.07 μm²), 160 (0.13 μm²), and 245 (0.2 μm²) quantum cells (area). The comparison results indicate that the designed circuits have advantages compared to other QCA circuits in terms of cost, area, and cell count.

     

Design of Improved Arithmetic Logic Unit in Quantum-Dot Cellular Automata

The quantum-dot cellular automata (QCA) can be replaced to overcome the limitation of CMOS technology. An arithmetic logic unit (ALU) is a basic structure of any computer devices. In this paper, design of improved single-bit arithmetic logic unit in quantum dot cellular automata is presented. The proposed structure for ALU has AND, OR, XOR and ADD operations. A unique 2:1 multiplexer, an ultra-efficient two-input XOR and a low complexity full adder are used in the proposed structure. Also, an extended design of this structure is provided for two-bit ALU in this paper. The proposed structure of ALU is simulated by QCADesigner and simulation result is evaluated. Evaluation results show that the proposed design has best performance in terms of area, complexity and delay compared to the previous designs.