Full potential equation, transonic flow regimes, Full Potential
Abstract
This paper delves into the application of the full potential equation in understanding and addressing the complexities of transonic flow, a critical area in aerospace engineering and energy dynamics. By conducting a comprehensive literature review, the study explores various facets of the full potential equation, including numerical simulation, flow characteristic analysis, and implications for aircraft design. Although the full potential equation effectively captures certain physical aspects of transonic flow, challenges arise when applied to complex geometries and unsteady flows. Issues of computational efficiency and accuracy are persistent obstacles that limit its application. Despite these limitations, the full potential equation remains a cornerstone in the study of transonic flows, providing essential insights that lay the groundwork for theoretical advancements in the field. The paper emphasizes the importance of ongoing research and refinement of solution techniques, which are crucial for enhancing the effectiveness of the full potential equation. Improved methodologies will not only address the complexities inherent in transonic flows but also enhance the equation’s performance in practical engineering scenarios, thereby advancing its utility in modern aerospace design and analysis.
