dynamic stabilization

简明释义

动力稳定

英英释义

例句

1.Engineers are focusing on dynamic stabilization to enhance the performance of robotic arms in manufacturing.

工程师们专注于动态稳定以提升制造业中机器人手臂的性能。

2.The dynamic stabilization system in the drone allows it to hover steadily despite wind gusts.

无人机中的动态稳定系统使其能够在风阵中稳定悬停。

3.The software uses dynamic stabilization algorithms to improve video quality during live streaming.

该软件使用动态稳定算法来提高直播时的视频质量。

4.The new aircraft design incorporates dynamic stabilization, which ensures smoother flight even in turbulent conditions.

新型飞机设计采用了动态稳定技术，这确保了在湍流条件下仍能实现更平稳的飞行。

5.In the context of marine engineering, dynamic stabilization helps maintain the balance of ships in rough seas.

在海洋工程中，动态稳定有助于在恶劣海况下保持船只的平衡。

作文

Dynamic stabilization is a concept that plays a crucial role in various fields, including engineering, robotics, and even human physiology. It refers to the ability of a system to maintain its stability while undergoing changes or disturbances. This concept can be observed in many aspects of life, from the way our bodies adjust to different environments to how machines operate efficiently under varying conditions. In this essay, I will explore the significance of dynamic stabilization (动态稳定性) in different contexts and its implications for future developments.In engineering, dynamic stabilization (动态稳定性) is essential for the design of structures and vehicles. For instance, consider the construction of skyscrapers in earthquake-prone areas. Engineers employ various techniques, such as base isolators and dampers, to ensure that these tall buildings can withstand seismic forces without collapsing. By allowing the structure to move independently from ground motion, dynamic stabilization (动态稳定性) helps to protect lives and property during natural disasters.Similarly, in the field of robotics, dynamic stabilization (动态稳定性) is vital for creating agile and adaptable machines. Robots designed for uneven terrains, such as those used in search and rescue missions, must maintain balance and stability while navigating obstacles. Advanced algorithms and sensors enable these robots to perform real-time adjustments, ensuring they remain upright and functional despite external challenges. This application of dynamic stabilization (动态稳定性) not only enhances robot performance but also expands their potential uses in various industries.Moreover, dynamic stabilization (动态稳定性) is observable in human physiology, particularly in our ability to maintain balance. The human body constantly adjusts to shifts in weight and movement through a complex interplay of sensory feedback and motor control. For example, when walking on a narrow beam, our brain processes information from our eyes and inner ear to make rapid adjustments that keep us from falling. This biological dynamic stabilization (动态稳定性) is crucial for daily activities and sports performance, highlighting the importance of stability in our lives.As technology advances, the applications of dynamic stabilization (动态稳定性) are likely to expand further. In the realm of autonomous vehicles, for instance, maintaining stability while navigating unpredictable road conditions is a significant challenge. Engineers are developing systems that can dynamically adjust the vehicle's suspension and steering based on real-time data, ensuring a smoother and safer ride. This innovation exemplifies how understanding and implementing dynamic stabilization (动态稳定性) can lead to safer transportation solutions.In conclusion, dynamic stabilization (动态稳定性) is a fundamental principle that underpins the functionality and safety of various systems in our world. From engineering marvels that withstand earthquakes to robots that navigate challenging environments and the human body's remarkable balance, the importance of dynamic stabilization (动态稳定性) cannot be overstated. As we continue to innovate and push the boundaries of technology, a deeper understanding of this concept will be essential for creating solutions that enhance our lives and ensure our safety in an ever-changing world.

动态稳定性是一个在工程、机器人技术甚至人体生理等多个领域中发挥关键作用的概念。它指的是一个系统在经历变化或干扰时维持其稳定性的能力。这一概念可以在生活的许多方面观察到，从我们身体如何适应不同环境到机器在变化条件下高效运作的方式。在这篇文章中，我将探讨动态稳定性在不同背景下的重要性及其对未来发展的影响。在工程学中，动态稳定性对于建筑物和车辆的设计至关重要。例如，考虑在地震多发地区建造摩天大楼。工程师采用各种技术，如基础隔震器和阻尼器，以确保这些高层建筑能够承受地震力而不倒塌。通过允许结构独立于地面运动，动态稳定性帮助保护生命和财产免受自然灾害的影响。同样，在机器人技术领域，动态稳定性对于创建灵活和适应性强的机器至关重要。为不平坦地形设计的机器人，例如用于搜索和救援任务的机器人，必须在导航障碍物时保持平衡和稳定。先进的算法和传感器使这些机器人能够进行实时调整，确保它们在外部挑战下保持直立和功能正常。这种动态稳定性的应用不仅增强了机器人的性能，还扩展了其在各个行业中的潜在用途。此外，动态稳定性在人体生理中也可以观察到，特别是在我们维持平衡的能力方面。人体通过感官反馈和运动控制的复杂相互作用，不断调整体重和运动的变化。例如，当在窄梁上行走时，我们的大脑处理来自眼睛和内耳的信息，以快速调整，防止摔倒。这种生物学上的动态稳定性对于日常活动和运动表现至关重要，突显了稳定性在我们生活中的重要性。随着科技的发展，动态稳定性的应用可能会进一步扩展。在自动驾驶汽车领域，保持稳定性以应对不可预测的道路条件是一个重大挑战。工程师正在开发能够根据实时数据动态调整车辆悬挂和转向的系统，以确保更平稳和安全的驾驶。这一创新例证了理解和实施动态稳定性可以导致更安全的交通解决方案。总之，动态稳定性是支撑我们世界中各种系统功能和安全的基本原则。从抵御地震的工程奇迹到导航复杂环境的机器人，以及人类身体的卓越平衡，动态稳定性的重要性不容小觑。随着我们不断创新和推动技术的边界，对这一概念的深入理解将是创造提升我们生活和确保我们在不断变化的世界中安全的解决方案的关键。