optimum coupling

简明释义

最佳耦合

英英释义

例句

1.To achieve better performance, the team analyzed the optimum coupling of the antenna with the transmitter.

为了获得更好的性能，团队分析了天线与发射器的最佳耦合。

2.The researchers focused on finding the optimum coupling parameters for the laser and fiber optics.

研究人员专注于寻找激光器和光纤的最佳耦合参数。

3.The engineers conducted tests to determine the optimum coupling between the motor and the gearbox for maximum efficiency.

工程师进行了测试，以确定电动机和齿轮箱之间的最佳耦合以实现最大效率。

4.Choosing the optimum coupling in a network design can significantly improve data transfer rates.

在网络设计中选择最佳耦合可以显著提高数据传输速率。

5.In this study, we evaluate the optimum coupling of various materials to enhance thermal conductivity.

在这项研究中，我们评估了不同材料的最佳耦合以增强热导率。

作文

In the realm of engineering and physics, the concept of optimum coupling plays a crucial role in ensuring that systems operate efficiently and effectively. Optimum coupling refers to the ideal connection between two components that maximizes energy transfer while minimizing losses. This principle can be applied in various fields, including mechanical systems, electrical circuits, and even biological systems. Understanding how to achieve optimum coupling is essential for engineers and scientists who strive to enhance performance and reliability in their designs.To illustrate the importance of optimum coupling, consider the example of an electric motor driving a pump. The motor must be perfectly aligned with the pump to ensure that the rotational energy is transferred without significant losses due to friction or misalignment. If the coupling is not optimized, it can lead to increased wear and tear on both components, reduced efficiency, and ultimately, failure of the system. Therefore, achieving optimum coupling in this scenario is vital for the longevity and efficiency of the entire system.Another area where optimum coupling is critical is in the field of telecommunications. Here, the term often refers to the connection between antennas and transmission lines. Engineers must design these connections to minimize signal loss and maximize the strength of the transmitted signals. By ensuring optimum coupling, they can improve the overall performance of communication systems, leading to clearer signals and faster data transmission rates.In addition to its applications in engineering, optimum coupling also has relevance in biology. For instance, in the study of ecosystems, researchers examine how different species interact and share resources. The concept can be applied to understand how certain plants and animals form symbiotic relationships that allow them to thrive. When these relationships reach a state of optimum coupling, both species benefit significantly, leading to greater biodiversity and stability within the ecosystem.Achieving optimum coupling often requires careful analysis and testing. Engineers may use simulation tools to model how different configurations affect performance. They might adjust parameters such as distance, angle, and material properties to find the best combination that leads to optimum coupling. This iterative process is crucial, as small changes can have significant impacts on efficiency and effectiveness.Moreover, the concept of optimum coupling extends beyond physical systems. In project management, for instance, teams must ensure that their efforts are well-coordinated to achieve the best results. This involves aligning goals, resources, and timelines to create a cohesive workflow. When team members work together in a state of optimum coupling, projects are more likely to succeed and meet deadlines.In conclusion, optimum coupling is a multifaceted concept that finds applications across various disciplines. Whether in engineering, telecommunications, biology, or project management, understanding and achieving optimum coupling is essential for maximizing efficiency and effectiveness. As technology continues to advance, the importance of this principle will only grow, making it a key focus for professionals seeking to innovate and improve systems in their respective fields.

在工程和物理领域，optimum coupling（最佳耦合）的概念在确保系统高效有效地运行中发挥着至关重要的作用。Optimum coupling指的是两个组件之间的理想连接，它最大化了能量传递，同时最小化了损耗。这个原则可以应用于多个领域，包括机械系统、电气电路，甚至生物系统。理解如何实现optimum coupling对工程师和科学家来说至关重要，他们力求在设计中提高性能和可靠性。为了说明optimum coupling的重要性，考虑一个电动机驱动泵的例子。电动机必须与泵完美对齐，以确保旋转能量在没有显著损失的情况下传递，这些损失可能是由于摩擦或错位造成的。如果耦合没有优化，可能会导致两个组件的磨损加剧、效率降低，最终导致系统故障。因此，在这种情况下，实现optimum coupling对于整个系统的耐用性和效率至关重要。Optimum coupling在电信领域同样至关重要。在这里，这个术语通常指天线与传输线之间的连接。工程师必须设计这些连接，以最小化信号损失并最大化传输信号的强度。通过确保optimum coupling，他们可以提高通信系统的整体性能，从而实现更清晰的信号和更快的数据传输速度。除了在工程中的应用外，optimum coupling在生物学中也具有相关性。例如，在生态系统研究中，研究人员考察不同物种如何相互作用和共享资源。这个概念可以应用于理解某些植物和动物如何形成共生关系，使它们能够繁衍生息。当这些关系达到optimum coupling的状态时，两种物种都会显著受益，从而促进生物多样性和生态系统的稳定性。实现optimum coupling通常需要仔细的分析和测试。工程师可能使用仿真工具来模拟不同配置如何影响性能。他们可能会调整距离、角度和材料特性等参数，以找到最佳组合，达到optimum coupling。这个迭代过程至关重要，因为小的变化可能对效率和效果产生重大影响。此外，optimum coupling的概念超越了物理系统。在项目管理中，例如，团队必须确保他们的努力协调一致，以实现最佳结果。这涉及到目标、资源和时间表的对齐，以创建一个有凝聚力的工作流程。当团队成员以optimum coupling的状态共同工作时，项目更有可能成功并按时完成。总之，optimum coupling是一个多方面的概念，涉及多个学科的应用。无论是在工程、电信、生物学还是项目管理中，理解和实现optimum coupling对于最大化效率和有效性至关重要。随着技术的不断进步，这一原则的重要性只会增加，成为专业人士寻求创新和改进各自领域系统的关键焦点。