coupling control

简明释义

耦合控制

英英释义

例句

1.The research focused on improving coupling control in dynamic systems.

研究集中于改善动态系统中的耦合控制。

2.To achieve better performance, the team applied coupling control techniques during testing.

为了获得更好的性能，团队在测试期间应用了耦合控制技术。

3.In robotics, coupling control is essential for coordinating multiple joints.

在机器人技术中，耦合控制对于协调多个关节至关重要。

4.The simulation results showed that coupling control significantly reduced oscillations.

仿真结果显示，耦合控制显著减少了振荡。

5.The engineer implemented coupling control to ensure the stability of the mechanical system.

工程师实施了耦合控制以确保机械系统的稳定性。

作文

In the field of engineering and control systems, the term coupling control refers to a method used to manage the interactions between different subsystems or components within a larger system. This concept is crucial in ensuring that various elements work harmoniously together, particularly when they are interdependent. For instance, in a robotic system, the movement of one joint may affect the position and motion of another joint. Therefore, effective coupling control is necessary to achieve coordinated and precise movements.One of the key challenges in coupling control is dealing with the nonlinearities that often arise in complex systems. Nonlinear systems can behave unpredictably, making it difficult to design control strategies that ensure stability and performance. Engineers and researchers have developed various techniques to address these challenges, including adaptive control, feedback linearization, and robust control methods. These approaches aim to minimize the effects of coupling between subsystems while maintaining overall system performance.Moreover, coupling control plays a significant role in multi-agent systems, where multiple agents or robots must collaborate to achieve a common goal. In such scenarios, the actions of one agent can directly influence the behavior of others. Therefore, implementing effective coupling control strategies is essential for ensuring that all agents can work together efficiently. This can involve designing communication protocols that allow agents to share information about their states and actions, enabling them to adjust their behaviors accordingly.The importance of coupling control extends beyond robotics and multi-agent systems. It is also vital in various applications, such as aerospace engineering, automotive systems, and manufacturing processes. For instance, in an aircraft, the control of the flight control surfaces must be carefully coordinated to ensure stable flight. Any misalignment or improper control could lead to dangerous situations. Thus, engineers must implement robust coupling control strategies to maintain safety and performance.In conclusion, coupling control is a fundamental concept in control systems that addresses the interactions between interconnected subsystems. By effectively managing these interactions, engineers can enhance the performance, stability, and safety of complex systems. As technology continues to advance, the development of more sophisticated coupling control techniques will be essential for tackling increasingly complex challenges in various fields. Understanding and mastering coupling control will be crucial for future engineers and researchers as they strive to create efficient and reliable systems that can operate seamlessly in a connected world.

在工程和控制系统领域，术语耦合控制指的是一种用于管理大型系统内不同子系统或组件之间相互作用的方法。这个概念对于确保各种元素能够和谐工作至关重要，特别是在它们相互依赖的情况下。例如，在机器人系统中，一个关节的运动可能会影响另一个关节的位置和运动。因此，有效的耦合控制是实现协调和精确运动所必需的。耦合控制面临的一个主要挑战是处理复杂系统中常常出现的非线性问题。非线性系统可能表现出不可预测的行为，这使得设计确保稳定性和性能的控制策略变得困难。工程师和研究人员已经开发出多种技术来应对这些挑战，包括自适应控制、反馈线性化和鲁棒控制方法。这些方法旨在最小化子系统之间的耦合影响，同时保持整体系统性能。此外，耦合控制在多智能体系统中也发挥着重要作用，在这种情况下，多个智能体或机器人必须协作以实现共同目标。在这样的场景中，一个智能体的行为可以直接影响其他智能体的行为。因此，实施有效的耦合控制策略对于确保所有智能体能够高效合作至关重要。这可能涉及设计通信协议，使智能体能够共享其状态和行为的信息，从而使它们能够相应地调整其行为。耦合控制的重要性不仅限于机器人技术和多智能体系统。它在航空航天工程、汽车系统和制造过程等各种应用中也至关重要。例如，在飞机中，飞行控制表面的控制必须经过仔细协调，以确保飞行的稳定性。任何不对齐或不当控制都可能导致危险情况。因此，工程师必须实施强健的耦合控制策略，以维护安全性和性能。总之，耦合控制是控制系统中的一个基本概念，它解决了相互连接的子系统之间的相互作用。通过有效管理这些相互作用，工程师可以提高复杂系统的性能、稳定性和安全性。随着技术的不断进步，开发更复杂的耦合控制技术将对于应对各个领域日益复杂的挑战至关重要。理解和掌握耦合控制将对未来的工程师和研究人员至关重要，因为他们努力创造能够在互联世界中无缝运行的高效可靠的系统。