cross coupling

简明释义

正交耦合

英英释义

例句

1.To improve the accuracy of measurements, engineers often need to account for cross coupling effects.

为了提高测量的准确性，工程师通常需要考虑交叉耦合效应。

2.When analyzing the system, we found that cross coupling between components was causing unexpected behavior.

在分析系统时，我们发现组件之间的交叉耦合导致了意外的行为。

3.In electrical engineering, cross coupling refers to the interaction between two circuits that affects their performance.

在电气工程中，交叉耦合指的是两个电路之间的相互作用，这会影响它们的性能。

4.The cross coupling of signals in communication systems can lead to interference and reduced clarity.

在通信系统中，信号的交叉耦合可能导致干扰和清晰度降低。

5.In a multi-channel system, cross coupling can result in crosstalk between channels.

在多通道系统中，交叉耦合可能导致通道之间的串音。

作文

In the realm of engineering and control systems, the term cross coupling refers to the interaction between two or more systems that can affect their performance. This phenomenon is particularly significant in multivariable control systems, where the output of one system may influence the input of another, leading to complex dynamics that must be managed effectively. Understanding cross coupling is essential for engineers who design systems that require precise control and coordination.For instance, consider a heating and cooling system in a large building. The temperature control for different zones can be interdependent; if one area is heated, it may inadvertently affect the cooling requirements of adjacent spaces. This interdependence is a classic example of cross coupling, where the performance of one system directly impacts another. Engineers must account for these interactions when designing control algorithms to ensure that the overall system operates efficiently and meets the desired specifications.Another area where cross coupling is prevalent is in robotics. In robotic systems, various joints and actuators work together to achieve coordinated movement. If one joint moves, it can impact the position and movement of others, creating a need for sophisticated control strategies to manage these interactions. By understanding cross coupling, roboticists can develop better algorithms that allow for smoother and more efficient operation.Moreover, cross coupling can also be observed in electrical circuits. In circuits with multiple components, the behavior of one component can influence others, leading to unintended consequences such as oscillations or signal distortion. Engineers must analyze these interactions to design circuits that function correctly under various conditions. This analysis often involves advanced mathematical techniques and simulations to predict how changes in one part of the circuit will affect others.The implications of cross coupling extend beyond engineering into fields like economics and ecology. In economics, the concept can describe how changes in one market can affect others, creating a ripple effect throughout the economy. Similarly, in ecology, the interactions between species within an ecosystem can lead to complex relationships that impact population dynamics and biodiversity.To effectively manage cross coupling, engineers and scientists often use models and simulations to predict system behavior. These tools allow them to visualize the interactions and make informed decisions about how to optimize performance. By acknowledging and addressing cross coupling, professionals can improve system reliability and efficiency, ultimately leading to better outcomes in various applications.In conclusion, the concept of cross coupling is a critical aspect of many fields, particularly in engineering and control systems. It highlights the importance of understanding the interactions between different systems and how they can influence each other. By mastering this concept, engineers can design more effective and efficient systems that meet the demands of modern technology. Whether in robotics, building management, or electrical engineering, recognizing and managing cross coupling is essential for achieving optimal performance and functionality.

在工程和控制系统领域，术语cross coupling指的是两个或多个系统之间的相互作用，这种相互作用可能会影响它们的性能。这种现象在多变量控制系统中尤为重要，其中一个系统的输出可能会影响另一个系统的输入，从而导致复杂的动态特征，需要有效管理。理解cross coupling对于设计需要精确控制和协调的系统的工程师至关重要。例如，考虑一个大型建筑中的供暖和制冷系统。不同区域的温度控制可能是相互依赖的；如果一个区域被加热，可能会无意中影响相邻空间的制冷需求。这种相互依赖性是cross coupling的经典例子，其中一个系统的性能直接影响另一个系统。工程师必须在设计控制算法时考虑这些相互作用，以确保整个系统高效运作并满足所需规格。cross coupling还广泛存在于机器人技术领域。在机器人系统中，各个关节和驱动器共同工作以实现协调运动。如果一个关节移动，它可能会影响其他关节的位置和运动，创造出对复杂控制策略的需求，以管理这些相互作用。通过理解cross coupling，机器人专家可以开发出更好的算法，使操作更加平滑和高效。此外，cross coupling在电路中也可以观察到。在具有多个组件的电路中，一个组件的行为可能会影响其他组件，导致意想不到的后果，例如振荡或信号失真。工程师必须分析这些相互作用，以设计在各种条件下正常工作的电路。这种分析通常涉及先进的数学技术和模拟，以预测电路中某一部分的变化将如何影响其他部分。cross coupling的影响超越了工程学，延伸到经济学和生态学等领域。在经济学中，这个概念可以描述一个市场的变化如何影响其他市场，从而在整个经济中产生涟漪效应。同样在生态学中，生态系统内物种之间的相互作用可以导致复杂的关系，影响种群动态和生物多样性。为了有效管理cross coupling，工程师和科学家通常使用模型和模拟来预测系统行为。这些工具使他们能够可视化相互作用，并就如何优化性能做出明智的决策。通过承认和解决cross coupling，专业人员可以提高系统的可靠性和效率，最终在各种应用中获得更好的结果。总之，cross coupling的概念是许多领域中的关键方面，尤其是在工程和控制系统中。它突显了理解不同系统之间的相互作用及其如何相互影响的重要性。通过掌握这一概念，工程师可以设计出更有效和高效的系统，以满足现代技术的需求。无论是在机器人技术、建筑管理还是电气工程中，认识和管理cross coupling对于实现最佳性能和功能至关重要。