large angle stability

简明释义

大倾角稳性

英英释义

例句

1.The simulation showed that the vehicle had poor large angle stability 大角度稳定性 when subjected to sudden maneuvers.

模拟显示该车辆在突然机动时具有较差的大角度稳定性。

2.To improve large angle stability 大角度稳定性, we adjusted the center of gravity of the model.

为了提高大角度稳定性，我们调整了模型的重心。

3.In robotics, achieving large angle stability 大角度稳定性 is crucial for maintaining balance in dynamic environments.

在机器人技术中，实现大角度稳定性对于在动态环境中保持平衡至关重要。

4.Engineers must consider large angle stability 大角度稳定性 when developing new drone technology.

工程师在开发新型无人机技术时必须考虑大角度稳定性。

5.The aircraft's design ensures adequate large angle stability 大角度稳定性 during steep turns.

该飞机的设计确保在急转弯时有足够的大角度稳定性。

作文

In the field of engineering and physics, the concept of large angle stability is crucial for understanding how systems behave under extreme conditions. This term refers to the ability of a system to maintain its equilibrium when subjected to significant angular displacements. For instance, in the design of vehicles, especially airplanes and spacecraft, ensuring large angle stability is essential for safety and performance. When an aircraft makes sharp turns or encounters turbulence, it must be able to return to a stable flight path without excessive pilot intervention. One of the key factors that contribute to large angle stability is the distribution of mass within the vehicle. A well-balanced design allows for better control during maneuvers, as the center of gravity plays a significant role in how forces act on the aircraft. Engineers often conduct simulations and tests to analyze the effects of various weight distributions and configurations on large angle stability. Moreover, the aerodynamic design of wings and fuselage shapes also impacts large angle stability. Wings that are designed with specific angles of attack can enhance stability during steep climbs or descents. The interaction between airflow and the surface of the wings can either stabilize or destabilize the aircraft, depending on the angle at which they operate. This is why aerodynamicists spend considerable time optimizing designs to ensure that large angle stability is achieved across various flight conditions. In addition to aerospace applications, large angle stability is also relevant in other areas such as robotics and mechanical systems. For example, robots designed to navigate uneven terrains must possess large angle stability to prevent tipping over. Engineers use gyroscopes and advanced control algorithms to maintain balance and stability, allowing these machines to function effectively in challenging environments. Furthermore, the principles of large angle stability can be applied to everyday objects as well. Consider a bicycle; when a rider leans into a turn, the bike must maintain its balance to avoid falling over. The design of the bicycle frame and the rider's body position work together to ensure large angle stability during sharp turns. This interplay of forces and angles highlights the importance of this concept in our daily lives. In conclusion, large angle stability is a fundamental aspect of various engineering disciplines, influencing the design and functionality of vehicles, robots, and even simple tools. Understanding this concept allows engineers to create safer and more efficient systems that can withstand extreme conditions. As technology continues to advance, the importance of large angle stability will likely grow, leading to innovations that enhance performance and safety in numerous applications.

在工程和物理学领域，大角稳定性的概念对于理解系统在极端条件下的行为至关重要。这个术语指的是一个系统在经历重大角位移时保持其平衡的能力。例如，在车辆的设计中，尤其是飞机和航天器，确保大角稳定性对安全性和性能至关重要。当飞机进行急转弯或遭遇气流扰动时，它必须能够在没有过多飞行员干预的情况下恢复到稳定的飞行路径。影响大角稳定性的一个关键因素是车辆内部的质量分布。良好的平衡设计可以在机动过程中提供更好的控制，因为重心在作用于飞机的力量上起着重要作用。工程师通常会进行模拟和测试，以分析不同重量分布和配置对大角稳定性的影响。此外，机翼和机身形状的空气动力学设计也会影响大角稳定性。以特定攻角设计的机翼可以增强在陡升或下降过程中的稳定性。气流与机翼表面的相互作用可以在操作的角度上稳定或不稳定飞机，这就是为什么空气动力学家花费大量时间优化设计，以确保在各种飞行条件下实现大角稳定性。除了航空航天应用外，大角稳定性在机器人和机械系统等其他领域也相关。例如，设计用于在不平坦地形上导航的机器人必须具备大角稳定性，以防止翻倒。工程师使用陀螺仪和先进的控制算法来保持平衡和稳定，使这些机器能够在具有挑战性的环境中有效运作。此外，大角稳定性的原理也可以应用于日常物品。考虑一下自行车；当骑自行车的人向转弯倾斜时，自行车必须保持平衡，以避免摔倒。自行车框架的设计和骑行者的身体位置共同作用，以确保在急转弯时保持大角稳定性。这种力量和角度之间的相互作用突显了这一概念在我们日常生活中的重要性。总之，大角稳定性是各种工程学科的基本方面，影响着车辆、机器人甚至简单工具的设计和功能。理解这一概念使工程师能够创造出更安全、更高效的系统，能够承受极端条件。随着技术的不断进步，大角稳定性的重要性可能会增加，导致在众多应用中提升性能和安全性的创新。