A VHDL-Based Modeling Approach for Rapid Functional Simulation and Verification of Adiabatic Circuits

Adiabatic logic is an energy-efficient technique, however, the time required in the design, validation, and debugging increases manifold for large-scale adiabatic system designs. In this endeavor, we present a hardware description language (HDL)-based modeling approach for 4-phase adiabatic logic design. The paper highlights the drawbacks of the existing approaches and proposes a new approach that captures the timing errors and detects the circuit's invalid operation due to mutually exclusive inputs being violated. We develop a model library containing the function of the four periods used in the trapezoidal power-clock and the adiabatic logic gates. The validation and verification of the proposed approach were done on the ISO-14443 standard benchmark circuit, a 16-bit cyclic redundancy check (CRC) circuit. The system modeled using HDL shows the timing agreement with the transistor-level SPICE simulations. The novel use of the four periods of a power-clock improves the robustness and reliability for the design and verification of large adiabatic systems.