definite-correction servomechanism

简明释义

间歇作用伺服机构

英英释义

例句

1.The engineer explained how the definite-correction servomechanism 定向修正伺服机构 works in maintaining the stability of the robotic arm.

工程师解释了如何使用定向修正伺服机构 definite-correction servomechanism 来维持机器人手臂的稳定性。

2.The research team focused on enhancing the performance of the definite-correction servomechanism 定向修正伺服机构 in autonomous vehicles.

研究小组专注于提升定向修正伺服机构 definite-correction servomechanism 在自主车辆中的性能。

3.Our latest model features an advanced definite-correction servomechanism 定向修正伺服机构 for improved accuracy.

我们的最新型号配备了先进的定向修正伺服机构 definite-correction servomechanism，以提高准确性。

4.In aerospace applications, a definite-correction servomechanism 定向修正伺服机构 is crucial for precise navigation.

在航空航天应用中，定向修正伺服机构 definite-correction servomechanism 对于精确导航至关重要。

5.The definite-correction servomechanism 定向修正伺服机构 helps in correcting errors in real-time during the manufacturing process.

在制造过程中，定向修正伺服机构 definite-correction servomechanism 有助于实时纠正错误。

作文

In the realm of engineering and control systems, the term definite-correction servomechanism refers to a specific type of feedback system designed to achieve precise control over a mechanical or electronic process. This mechanism is essential in various applications, ranging from robotics to aerospace engineering, where accuracy and responsiveness are critical. The concept of a servomechanism itself involves a looped control system that continuously adjusts its output based on feedback from sensors, ensuring that the desired outcome is consistently met.The functionality of a definite-correction servomechanism lies in its ability to correct deviations from a predetermined set point. For instance, imagine a robotic arm tasked with assembling intricate components. If the arm deviates from its intended path due to external forces or inaccuracies in its initial positioning, the definite-correction servomechanism steps in to make real-time adjustments. By analyzing feedback from position sensors, it can determine how far off course the arm has strayed and apply the necessary corrections to bring it back on track.One of the key advantages of using a definite-correction servomechanism is its reliability in maintaining performance under varying conditions. In many engineering scenarios, disturbances such as changes in load, temperature fluctuations, or wear and tear can affect the performance of a system. However, the feedback loop inherent in this mechanism allows for continuous monitoring and adjustment, enabling the system to adapt to these changes without significant loss of accuracy.Moreover, the implementation of a definite-correction servomechanism can lead to enhanced efficiency in operations. By ensuring that systems operate within their optimal parameters, energy consumption can be minimized, and wear on mechanical components can be reduced. This not only extends the lifespan of the equipment but also contributes to cost savings in industrial settings.Furthermore, the design of a definite-correction servomechanism can vary significantly depending on the specific application. For example, in an automotive context, such mechanisms may be used in cruise control systems to maintain a constant speed despite changes in terrain or traffic conditions. In contrast, in the field of telecommunications, they might be employed to stabilize signals in satellite communication systems, ensuring consistent data transmission.In conclusion, the definite-correction servomechanism plays a pivotal role in modern engineering by providing a robust solution for achieving precise control in dynamic environments. Its ability to continuously correct deviations, adapt to changing conditions, and improve operational efficiency makes it an invaluable component in a wide range of technological applications. As industries continue to evolve and demand higher levels of precision and reliability, the significance of the definite-correction servomechanism will only grow, paving the way for innovations that enhance our everyday lives.

在工程和控制系统领域，术语明确修正伺服机制指的是一种特定类型的反馈系统，旨在对机械或电子过程实现精确控制。该机制在各种应用中至关重要，从机器人技术到航空航天工程，在这些领域中，准确性和响应性是关键。伺服机制本身的概念涉及一个循环控制系统，该系统根据传感器的反馈不断调整其输出，以确保始终达到预期结果。明确修正伺服机制的功能在于其能够修正偏离预定设定点的情况。例如，想象一下一个被指派组装复杂组件的机器人手臂。如果由于外部力量或初始定位的不准确，手臂偏离了其预定路径，那么明确修正伺服机制就会介入进行实时调整。通过分析位置传感器的反馈，它可以确定手臂偏离了多远，并施加必要的修正，将其带回正轨。使用明确修正伺服机制的一个主要优点是其在变化条件下保持性能的可靠性。在许多工程场景中，负载变化、温度波动或磨损等干扰都可能影响系统的性能。然而，这种机制固有的反馈循环允许持续监测和调整，使系统能够适应这些变化，而不会显著降低准确性。此外，实施明确修正伺服机制可以提高操作效率。通过确保系统在其最佳参数内运行，可以最小化能耗，并减少机械组件的磨损。这不仅延长了设备的使用寿命，还为工业环境中的成本节约做出了贡献。此外，明确修正伺服机制的设计可以根据具体应用显著不同。例如，在汽车上下文中，此类机制可能用于巡航控制系统，以在地形或交通条件变化时维持恒定速度。相反，在电信领域，它们可能用于稳定卫星通信系统中的信号，确保数据传输的一致性。总之，明确修正伺服机制在现代工程中发挥着关键作用，通过提供一种强大的解决方案来实现动态环境中的精确控制。它能够不断修正偏差，适应变化条件，提高操作效率，使其成为广泛技术应用中不可或缺的组成部分。随着各行业的不断发展，对更高水平的精确性和可靠性的需求，明确修正伺服机制的重要性将只会增加，为增强我们日常生活的创新铺平道路。