Abstract
Voltage droop is a significant challenge in high-speed digital circuits, impacting the reliability and performance of electronic systems. This paper introduces a novel approach based on a Modified Ohm's Law to address this issue. By incorporating nonlinear resistance effects, the Modified Ohm's Law provides a more accurate representation of circuit behavior, particularly under dynamic conditions. Through a rigorous simulation framework, the behavior of power supply models under varying load conditions is analyzed. The paper systematically examines circuit responses, load variations, and power supply dynamics, integrating both Standard and Modified Ohm's Law to compare their effectiveness in voltage regulation. The simulation results indicate that the Modified Ohm's Law provides a more accurate prediction of voltage behavior, particularly under rapid load changes, leading to significant improvements in voltage stability. The applied parameter sweep analyses reveal that adjusting the time constant of the power supply within the Modified Ohm's Law framework yields superior voltage regulation compared to traditional methods. Additionally, the analysis of frequency and amplitude variations demonstrates the robustness of the Modified Ohm's Law in maintaining voltage stability across different operational scenarios. This approach effectively addresses the nonlinearities in resistance, reducing voltage droop and enhancing the reliability of high-speed digital circuits. The findings demonstrate the potential of the Modified Ohm's Law in practical applications, suggesting further research and real-world experimentation to fully explore its benefits and implementation strategies. This work contributes to the advancement of voltage regulation techniques, offering a robust solution to the persistent problem of voltage droop in modern electronic systems.
Published Version
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call