IDPAL – A Partially-Adiabatic Energy-Efficient Logic Family: Theory and Applications to Secure Computing

Low-power circuits and issues associated with them have gained a significant amount of attention in recent years due to the boom in portable electronic devices. Historically, low-power operation relied heavily on technology scaling and reduced operating voltage, however this trend has been slowing down recently due to the increased power density on chips. This dissertation introduces a new very-low power partially-adiabatic logic family called Input-Decoupled Partially-Adiabatic Logic (IDPAL) with applications in low-power circuits. Experimental results show that IDPAL reduces energy usage by 79% compared to equivalent CMOS implementations and by 25% when compared to the best adiabatic implementation. Experiments ranging from a simple buffer/inverter up to a 32-bit multiplier are explored and result in consistent energy savings, showing that IDPAL could be a viable candidate for a low-power circuit implementation. This work also shows an application of IDPAL to secure low-power circuits against power analysis attacks. It is often assumed that encryption algorithms are perfectly secure against attacks, however, most times attacks using side channels on the hardware implementation of an encryption operation are not investigated. Power analysis attacks are a subset of side channel attacks and can be implemented by measuring the power used by a circuit during an encryption operation in order to obtain secret information from the circuit under attack. Most of the previously proposed solutions for power analysis attacks use a large amount of power and are unsuitable for a low-power application. The almost-equal energy consumption for any given input in an IDPAL circuit suggests that this logic family is a good candidate for securing low-power circuits again power analysis attacks. Experimental results ranging from small circuits to large multipliers are performed and the power-analysis attack resistance of IDPAL is investigated. Results show that IDPAL circuits are not only low-power but also the most secure against power analysis attacks when compared to other adiabatic low-power circuits. Finally, a hybrid adiabatic-CMOS microprocessor design is presented. The proposed microprocessor uses IDPAL for the implementation of circuits with high switching activity (e.g. ALU) and CMOS logic for other circuits (e.g. memory, controller). An adiabatic-CMOS interface for transforming adiabatic signals to square-wave signals is presented and issues associated with a hybrid implementation and their solutions are also discussed

Digital logic circuit design using adiabatic approach

A major challenge for the circuit designers nowadays is to meet the demand for low power, especially those used in portable and wearable devices which have limited energy power supply. The reasons of designing low power consumption circuit are to reduce energy usage and minimize dissipation of heat. Adiabatic technique is an attractive approach to obtain power optimization where some of the charge in capacitance can be recycled instead of being dissipated as heat. In this thesis, a methodology for designing sequential adiabatic circuits employing a single-phase power clock was investigated. Initially, methods to simulate dynamic power were analysed by identifying a better and reliable method to simulate adiabatic dynamic power. In addition, a method to validate the output voltage swing was presented. The relationship between voltage swing and power dissipation was analysed. Then, several adiabatic sequential D flip flops (DFF) designs which make use of combinational adiabatic circuit design based on quasi-adiabatic were proposed and suitable types of alternating current power supply which influence dynamic power were analysed and selected. The functionality and performance of the proposed circuits were compared against other adiabatic and traditional Complimentary Metal-Oxide Semiconductor (CMOS) circuits and verified to function up to 1 GHz operating region. Besides the circuits, the layout of the proposed sequential adiabatic design was also produced. All simulations were carried out using 0.25 ^m CMOS technology parameters using Tanner Electronic Design Aided and HSPICE tools. The findings showed that the proposed combinational circuit had less transistor count, lower power dissipation with lower voltage swing as compared to reference adiabatic circuits. Furthermore, the proposed sequential DFF circuit showed 25% less power dissipation compared to traditional CMOS

A Technology Aware Magnetic QCA NCL-HDL Architecture

Magnetic Quantum Dot Cellular Automata (MQCA) have been recently proposed as an attractive implementation of QCA as a possible CMOS technology substitute. Marking a difference with respect to previous contributions, in this work we show that it is possible to develop and describe complex MQCA computational blocks strongly linking technology and having in mind a feasible realization. Thus, we propose a practicable clock structure for MQCA baptised "snake-clock", we stick to this while developing a system level Hardware Description Language (HDL) based description of an architectural block, and we suggest a delay insensitive Null Convention Logic (NCL) implementation for the magnetic case so that the "layout=timing" problem can be solved. Furthermore we include in our model aspects critically related to technology and real production, that is timing, power and layout, and we present the preliminary steps of our experiments, the results of which will be included in the architecture descriptio

Beyond Moore's technologies: operation principles of a superconductor alternative

The predictions of Moore's law are considered by experts to be valid until 2020 giving rise to "post-Moore's" technologies afterwards. Energy efficiency is one of the major challenges in high-performance computing that should be answered. Superconductor digital technology is a promising post-Moore's alternative for the development of supercomputers. In this paper, we consider operation principles of an energy-efficient superconductor logic and memory circuits with a short retrospective review of their evolution. We analyze their shortcomings in respect to computer circuits design. Possible ways of further research are outlined.Comment: OPEN ACCES

Adiabatic Approach for Low-Power Passive Near Field Communication Systems

This thesis tackles the need of ultra-low power electronics in the power limited passive Near Field Communication (NFC) systems. One of the techniques that has proven the potential of delivering low power operation is the Adiabatic Logic Technique. However, the low power benefits of the adiabatic circuits come with the challenges due to the absence of single opinion on the most energy efficient adiabatic logic family which constitute appropriate trade-offs between computation time, area and complexity based on the circuit and the power-clocking schemes. Therefore, five energy efficient adiabatic logic families working in single-phase, 2-phase and 4-phase power-clocking schemes were chosen. Since flip-flops are the basic building blocks of any sequential circuit and the existing flip-flops are MUX-based (having more transistors) design, therefore a novel single-phase, 2-phase and 4-phase reset based flip-flops were proposed. The performance of the multi-phase adiabatic families was evaluated and compared based on the design examples such as 2-bit ring counter, 3-bit Up-Down counter and 16-bit Cyclic Redundancy Check (CRC) circuit (benchmark circuit) based on ISO 14443-3A standard. Several trade-offs, design rules, and an appropriate range for the supply voltage scaling for multi-phase adiabatic logic are proposed. Furthermore, based on the NFC standard (ISO 14443-3A), data is frequently encoded using Manchester coding technique before transmitting it to the reader. Therefore, if Manchester encoding can be implemented using adiabatic logic technique, energy benefits are expected. However, adiabatic implementation of Manchester encoding presents a challenge. Therefore, a novel method for implementing Manchester encoding using adiabatic logic is proposed overcoming the challenges arising due to the AC power-clock. Other challenges that come with the dynamic nature of the adiabatic gates and the complexity of the 4-phase power-clocking scheme is in synchronizing the power-clock v phases and the time spent in designing, validation and debugging of errors. This requires a specific modelling approach to describe the adiabatic logic behaviour at the higher level of abstraction. However, describing adiabatic logic behaviour using Hardware Description Languages (HDLs) is a challenging problem due to the requirement of modelling the AC power-clock and the dual-rail inputs and outputs. Therefore, a VHDL-based modelling approach for the 4-phase adiabatic logic technique is developed for functional simulation, precise timing analysis and as an improvement over the previously described approaches

Quantum-dot Cellular Automata: Review Paper

Quantum-dot Cellular Automata (QCA) is one of the most important discoveries that will be the successful alternative for CMOS technology in the near future. An important feature of this technique, which has attracted the attention of many researchers, is that it is characterized by its low energy consumption, high speed and small size compared with CMOS.  Inverter and majority gate are the basic building blocks for QCA circuits where it can design the most logical circuit using these gates with help of QCA wire. Due to the lack of availability of review papers, this paper will be a destination for many people who are interested in the QCA field and to know how it works and why it had taken lots of attention recentl

VHDL-based Modelling Approach for the Digital Simulation of 4-phase Adiabatic Logic Design

In comparison to conventional CMOS (non-adiabatic logic), the verification of the functionality and the low energy traits of adiabatic logic techniques are generally performed using transient simulations at the transistor level. However, as the size and complexity of the adiabatic system increases, the amount of time required to design and simulate also increases. Moreover, due to the complexity of synchronizing the power-clock phases, debugging of errors becomes difficult too thus, increasing the overall verification time. This paper proposes a VHSIC Hardware Descriptive Language (VHDL) based modelling approach for developing models representing the 4-phase adiabatic logic designs. Using the proposed approach, the functional errors can be detected and corrected at an early design stage so that when designing adiabatic circuits at the transistor level, the circuit performs correctly and the time for debugging the errors can substantially be reduced. The function defining the four periods of the trapezoidal AC power-clock is defined in a package which is followed by designing a library containing the behavioral VHDL models of adiabatic logic gates namely; AND/NAND, OR/NOR and XOR/XNOR. Finally, the model library is used to develop and verify the structural VHDL representation of the 4-phase 2-bit ring-counter and 3-bit up-down counter, as a design example that demonstrates the practicality of the proposed approach