Ultra low power adiabatic logic using diode connected DC biased PFAL logic

With the continuous scaling down of technology in the field of integrated circuit design, low power dissipation has become one of the primary focuses of the research. With the increasing demand for low power devices, adiabatic logic gates prove to be an effective solution. This paper briefs on different adiabatic logic families such as ECRL (Efficient Charge Recovery Logic), 2N-2N2P and PFAL (Positive Feedback Adiabatic Logic), and presents a new proposed circuit based on the PFAL logic circuit. The aim of this paper is to simulate various logic gates using PFAL logic circuits and with the proposed logic circuit, and hence to compare the effectiveness in terms of average power dissipation and delay at different frequencies. This paper further presents implementation of C17 and C432 benchmark circuits, using the proposed logic circuit and the conventional PFAL logic circuit to compare effectiveness of the proposed logic circuit in terms of average power dissipation at different frequencies. All simulations are carried out by using HSPICE Simulator at 65 nm technology at different frequency ranges. Finally, average power dissipation characteristics are plotted with the help of graphs, and comparisons are made between PFAL logic family and new proposed PFAL logic family

Adiabatic technique based low power synchronous counter design

The performance of integrated circuits is evaluated by their design architecture, which ensures high reliability and optimizes energy. The majority of the system-level architectures consist of sequential circuits. Counters are fundamental blocks in numerous very large-scale integration (VLSI) applications. The T-flip-flop is an important block in synchronous counters, and its high-power consumption impacts the overall effectiveness of the system. This paper calculates the power dissipation (PD), power delay product (PDP), and latency of the presented T flip-flop. To create a 2-bit synchronous counter based on the novel T flip-flops, a performance matrix such as PD, latency, and PDP is analyzed. The analysis is carried out at 100 and 10 MHz frequencies with varying temperatures and operating voltages. It is observed that the presented counter design has a lesser power requirement and PDP compared to the existing counter architectures. The proposed T-flip-flop design at the 45 nm technology node shows an improvement of 30%, 76%, and 85% in latency, PD, and PDP respectively to the 180 nm node at 10 MHz frequency. Similarly, the proposed counter at the 45 nm technology node shows 96% and 97% improvement in power dissipation, delay, and PDP respectively compared to the 180 nm at 10 MHz frequency

Implementation of Full Adder Using CMOS And DFAL Adiabatic Logic

Power dissipation has always been a major concern in today’s world. With increase in technology, sizing and power consumption is a great analyzing parameter. Thus, each year new technologies are designed to meet the requirements using adiabatic techniques. Adder possesses importance in designing of ALU, digital signal processing, ripple counter.  Designing of adder using conventional technique (CMOS) often create complexity and sizing issue with more energy dissipation. In this way, thus structuring adder with adiabatic system to determine previously mentioned issues. Here in this paper full adder is planned first utilizing CMOS procedure and after that utilizing DFAL (diode free adiabatic rationale) method and accordingly contrasting outcomes and ordinary cmos circuit