residual dynamic stability

简明释义

剩余动稳性

英英释义

例句

1.In robotics, ensuring residual dynamic stability 残余动态稳定性 allows the robot to recover from disturbances.

在机器人技术中，确保残余动态稳定性使机器人能够从干扰中恢复。

2.The study focused on improving the residual dynamic stability 残余动态稳定性 of high-speed trains.

这项研究集中于提高高速列车的残余动态稳定性。

3.To enhance safety, the team analyzed the residual dynamic stability 残余动态稳定性 of the new suspension system.

为了提高安全性，团队分析了新悬挂系统的残余动态稳定性。

4.The bridge was designed with enhanced residual dynamic stability 残余动态稳定性 to withstand unexpected seismic activity.

这座桥的设计增强了残余动态稳定性，以抵御意外的地震活动。

5.Engineers must consider the residual dynamic stability 残余动态稳定性 of the aircraft during turbulent weather conditions.

工程师必须考虑飞机在恶劣天气条件下的残余动态稳定性。

作文

In the realm of engineering and physics, particularly in the study of dynamic systems, the concept of residual dynamic stability plays a crucial role. This term refers to the ability of a system to maintain stability after being subjected to disturbances or changes in its environment. Understanding residual dynamic stability is essential for designing systems that can withstand unexpected shocks while continuing to function effectively. To illustrate this concept, let us consider an example from aerospace engineering. When an aircraft experiences turbulence, it is subjected to various forces that can disrupt its flight path. The residual dynamic stability of the aircraft determines how well it can return to a stable flight condition after the disturbance. Engineers must meticulously analyze the aircraft's design to ensure that it possesses adequate residual dynamic stability, allowing it to recover smoothly without excessive oscillations or loss of control. Moreover, residual dynamic stability is not limited to aviation; it is also applicable in other fields such as civil engineering and robotics. For instance, in the construction of tall buildings, architects must consider how structures will respond to wind loads or seismic activity. A building with high residual dynamic stability can endure these forces without collapsing or experiencing significant damage. Similarly, in robotics, the residual dynamic stability of a robot affects its ability to navigate uneven terrains or recover from slips. The mathematical modeling of residual dynamic stability involves complex calculations that take into account various factors, including mass distribution, damping ratios, and external forces. Engineers use simulations to predict how a system will behave under different conditions, ensuring that designs meet safety and performance standards. Furthermore, the importance of residual dynamic stability extends beyond engineering applications; it can also be observed in ecological systems. For example, a forest ecosystem exhibits residual dynamic stability when it can recover from events such as wildfires or pest infestations. The resilience of the ecosystem allows it to bounce back and maintain its biodiversity, which is vital for the overall health of the environment. In conclusion, residual dynamic stability is a fundamental concept that underpins the design and analysis of various dynamic systems across multiple disciplines. Its significance lies in the ability of systems to maintain stability and functionality even after experiencing disturbances. As we continue to innovate and develop new technologies, understanding and enhancing residual dynamic stability will be paramount in ensuring safety, efficiency, and resilience in our engineered environments and natural ecosystems.

在工程和物理的领域，特别是在动态系统的研究中，残余动态稳定性这一概念起着至关重要的作用。这个术语指的是一个系统在遭受扰动或环境变化后保持稳定的能力。理解残余动态稳定性对于设计能够承受意外冲击并持续有效运作的系统至关重要。为了说明这一概念，让我们考虑一个来自航空工程的例子。当一架飞机经历湍流时，它会受到各种力量的影响，这可能会干扰其飞行路径。飞机的残余动态稳定性决定了它在干扰后能够多好地恢复到稳定的飞行状态。工程师必须仔细分析飞机的设计，以确保其具备足够的残余动态稳定性，使其能够平稳恢复，而不会出现过度的振荡或失去控制。此外，残余动态稳定性不仅限于航空领域；它在土木工程和机器人等其他领域也同样适用。例如，在高层建筑的建造中，建筑师必须考虑结构如何应对风载荷或地震活动。具有高残余动态稳定性的建筑能够承受这些力量，而不发生倒塌或遭受重大损坏。同样，在机器人技术中，机器人的残余动态稳定性影响其在不平坦地形上导航或从滑倒中恢复的能力。残余动态稳定性的数学建模涉及复杂的计算，考虑到多个因素，包括质量分布、阻尼比和外部力量。工程师使用模拟来预测系统在不同条件下的行为，确保设计符合安全和性能标准。此外，残余动态稳定性的重要性超越了工程应用；它还可以在生态系统中观察到。例如，森林生态系统表现出残余动态稳定性，当其能够从野火或虫害等事件中恢复时。这种生态系统的弹性使其能够反弹并维持生物多样性，这对环境的整体健康至关重要。总之，残余动态稳定性是支撑各个学科动态系统设计与分析的基本概念。其重要性在于系统即使在经历扰动后，仍能保持稳定性和功能。随着我们不断创新和开发新技术，理解和增强残余动态稳定性将是确保我们工程环境和自然生态系统安全、高效和韧性的关键。