lateral oscillation

简明释义

横振动

英英释义

例句

1.In robotics, lateral oscillation 横向振荡 can affect the precision of movement in robotic arms.

在机器人技术中，lateral oscillation 横向振荡会影响机械臂的运动精度。

2.Researchers are studying the effects of lateral oscillation 横向振荡 on the performance of high-speed trains.

研究人员正在研究lateral oscillation 横向振荡对高速列车性能的影响。

3.The pilot was trained to handle the aircraft's lateral oscillation 横向振荡 during turbulence.

飞行员接受了应对飞机在颠簸中发生的lateral oscillation 横向振荡的训练。

4.The engineer noted that the bridge experienced significant lateral oscillation 横向振荡 during the strong winds.

工程师注意到，在强风中，桥梁经历了显著的lateral oscillation 横向振荡。

5.To improve stability, the team designed a damping system to reduce lateral oscillation 横向振荡 in the new skyscraper.

为了提高稳定性，团队设计了一种阻尼系统，以减少新摩天大楼中的lateral oscillation 横向振荡。

作文

Lateral oscillation is a term often used in engineering and physics to describe the side-to-side movement of an object. This phenomenon can be observed in various systems, including vehicles, buildings, and even biological organisms. Understanding Lateral Oscillation (横向摆动) is crucial for designing stable structures and ensuring safety in mechanical systems.In vehicles, Lateral Oscillation (横向摆动) can affect handling and ride comfort. For instance, when a car takes a sharp turn, it may experience forces that cause the body to sway from side to side. Engineers must account for these movements when designing suspension systems to ensure that the vehicle remains stable and controllable. If a car experiences excessive Lateral Oscillation (横向摆动), it can lead to loss of control, making it essential to find a balance between comfort and performance.Similarly, in civil engineering, understanding Lateral Oscillation (横向摆动) is vital for constructing buildings and bridges that can withstand lateral forces, such as those caused by wind or earthquakes. Structures must be designed to absorb and dissipate these forces to prevent catastrophic failures. For example, skyscrapers often incorporate damping systems to reduce Lateral Oscillation (横向摆动) during high winds, enhancing their stability and safety.Moreover, Lateral Oscillation (横向摆动) is also relevant in the field of biomechanics. Many animals exhibit lateral movements while running or swimming, which can be analyzed to improve performance in sports or to develop better robotic systems. By studying how animals manage Lateral Oscillation (横向摆动), researchers can create more efficient and agile robots that mimic these natural movements.In the context of aerodynamics, Lateral Oscillation (横向摆动) can also refer to the side-to-side motion of an aircraft during flight. Pilots must be aware of this phenomenon, especially during turbulent conditions, as it can impact the stability of the aircraft. Engineers use simulations and wind tunnel testing to study Lateral Oscillation (横向摆动) in aircraft design, ensuring that planes can handle lateral forces effectively.In summary, Lateral Oscillation (横向摆动) is a significant concept across multiple disciplines, from automotive engineering to architecture and biomechanics. Its implications are far-reaching, influencing the design and functionality of various systems. As technology advances, the understanding and management of Lateral Oscillation (横向摆动) will continue to evolve, leading to safer and more efficient designs in our everyday lives. Whether in vehicles, buildings, or even robotics, recognizing the importance of Lateral Oscillation (横向摆动) is essential for innovation and safety.

横向摆动是一个常用于工程和物理学的术语，用来描述物体的左右移动。这种现象可以在各种系统中观察到，包括车辆、建筑物，甚至生物有机体。理解Lateral Oscillation（横向摆动）对于设计稳定的结构和确保机械系统的安全至关重要。在车辆中，Lateral Oscillation（横向摆动）会影响操控性和乘坐舒适性。例如，当一辆汽车急转弯时，它可能会受到导致车身左右摇摆的力的影响。工程师必须在设计悬挂系统时考虑这些运动，以确保车辆保持稳定和可控。如果一辆车经历过度的Lateral Oscillation（横向摆动），可能会导致失去控制，因此找到舒适性和性能之间的平衡至关重要。同样，在土木工程中，理解Lateral Oscillation（横向摆动）对于建造能够承受横向力量的建筑物和桥梁至关重要，例如风或地震造成的力量。结构必须设计成能够吸收和耗散这些力量，以防止灾难性失败。例如，摩天大楼通常结合阻尼系统，以减少高风中的Lateral Oscillation（横向摆动），增强其稳定性和安全性。此外，Lateral Oscillation（横向摆动）在生物力学领域也很相关。许多动物在奔跑或游泳时表现出横向运动，这可以被分析以提高运动表现或开发更好的机器人系统。通过研究动物如何管理Lateral Oscillation（横向摆动），研究人员可以创造出更高效、更灵活的机器人，模仿这些自然运动。在空气动力学的背景下，Lateral Oscillation（横向摆动）也可以指飞机在飞行过程中的左右运动。飞行员必须意识到这一现象，特别是在湍流条件下，因为这会影响飞机的稳定性。工程师使用模拟和风洞测试来研究飞机设计中的Lateral Oscillation（横向摆动），确保飞机能够有效应对横向力量。总之，Lateral Oscillation（横向摆动）是多个学科中的重要概念，从汽车工程到建筑和生物力学。它的影响深远，影响着各种系统的设计和功能。随着技术的进步，对Lateral Oscillation（横向摆动）的理解和管理将继续发展，导致我们日常生活中更安全和更高效的设计。无论是在车辆、建筑物还是机器人中，认识到Lateral Oscillation（横向摆动）的重要性对创新和安全至关重要。