track deviation limit

简明释义

航迹偏离极限

英英释义

例句

1.The system will trigger an alert if the vehicle exceeds the track deviation limit (轨道偏差限制).

如果车辆超过了轨道偏差限制，系统将发出警报。

2.To ensure safety, we need to monitor the track deviation limit (轨道偏差限制) closely during the test runs.

为了确保安全，我们需要在测试运行期间密切监控轨道偏差限制。

3.Adjusting the track deviation limit (轨道偏差限制) can help improve the performance of the automated system.

调整轨道偏差限制可以帮助改善自动化系统的性能。

4.Failure to adhere to the track deviation limit (轨道偏差限制) may result in significant operational risks.

未能遵守轨道偏差限制可能会导致重大操作风险。

5.The engineering team is reviewing the track deviation limit (轨道偏差限制) to ensure compliance with industry standards.

工程团队正在审查轨道偏差限制以确保符合行业标准。

作文

In the field of engineering and technology, precision is paramount. One critical aspect that engineers often focus on is the measurement and control of various parameters to ensure optimal performance. Among these parameters, the concept of track deviation limit plays a significant role in systems that require strict adherence to specified paths or guidelines. The track deviation limit refers to the maximum allowable deviation from a predetermined path or track that a system can experience before corrective actions are necessary. This limit is essential in various applications, including transportation systems, robotics, and manufacturing processes.For instance, consider a high-speed train system. The track deviation limit is crucial for maintaining safety and efficiency. If a train deviates beyond this limit due to external factors such as weather conditions or mechanical failures, it could lead to catastrophic consequences, including derailments. Therefore, engineers must establish a well-defined track deviation limit based on extensive research, simulations, and real-world testing. This involves analyzing historical data, understanding environmental influences, and implementing advanced technologies to monitor deviations in real-time.In robotics, the track deviation limit is equally important. Robots are often programmed to follow specific paths to perform tasks accurately. For example, in automated manufacturing, a robotic arm may need to follow a precise trajectory to assemble components. If the arm deviates beyond the track deviation limit, it could result in misaligned parts or even damage to the equipment. To prevent such issues, engineers use sensors and feedback mechanisms to constantly monitor the robot's position and make necessary adjustments to stay within the defined limits.Moreover, the track deviation limit is not only about preventing errors but also about enhancing overall system performance. By optimizing these limits, engineers can improve efficiency, reduce wear and tear on machinery, and extend the lifespan of equipment. For instance, in aerospace engineering, aircraft must adhere to strict track deviation limits during flight to ensure stability and safety. Pilots and autopilot systems continuously monitor their position relative to the planned flight path, making adjustments as needed to remain within the established limits.In conclusion, the concept of track deviation limit is vital across various industries where precision and safety are critical. It serves as a benchmark for acceptable performance, guiding engineers and operators in maintaining optimal functionality. Understanding and implementing appropriate track deviation limits can significantly enhance the reliability and efficiency of complex systems, ultimately leading to safer and more effective operations. As technology continues to advance, the importance of accurately defining and adhering to these limits will only grow, emphasizing the need for ongoing research and development in this area.

在工程和技术领域，精确性至关重要。工程师常常关注的一个关键方面是测量和控制各种参数，以确保最佳性能。在这些参数中，轨道偏差限制的概念在需要严格遵循特定路径或指引的系统中发挥着重要作用。轨道偏差限制指的是系统在经历的最大允许偏离预定路径或轨道的程度，超过此限度就需要采取纠正措施。这个限制在各种应用中都是必不可少的，包括运输系统、机器人技术和制造过程。例如，考虑高速列车系统。轨道偏差限制对于保持安全和效率至关重要。如果由于天气条件或机械故障等外部因素，列车的偏离超出了这一限制，可能会导致灾难性的后果，包括出轨。因此，工程师必须根据广泛的研究、模拟和实际测试建立明确的轨道偏差限制。这涉及分析历史数据、理解环境影响，并实施先进技术以实时监控偏差。在机器人技术中，轨道偏差限制同样重要。机器人通常被编程为遵循特定路径以准确执行任务。例如，在自动化制造中，机器人手臂可能需要遵循精确的轨迹来组装组件。如果手臂偏离了轨道偏差限制，可能会导致部件错位甚至损坏设备。为了防止此类问题，工程师使用传感器和反馈机制不断监控机器人的位置，并进行必要的调整，以保持在定义的限制范围内。此外，轨道偏差限制不仅仅是为了防止错误，还在于提高整体系统性能。通过优化这些限制，工程师可以提高效率、减少机械磨损，并延长设备的使用寿命。例如，在航空航天工程中，飞机在飞行过程中必须遵守严格的轨道偏差限制以确保稳定性和安全性。飞行员和自动驾驶系统不断监控其相对于计划飞行路径的位置，并根据需要进行调整，以保持在既定限制范围内。总之，轨道偏差限制的概念在各个行业中至关重要，尤其是在精确性和安全性至关重要的地方。它作为可接受性能的基准，引导工程师和操作人员保持最佳功能。理解和实施适当的轨道偏差限制可以显著增强复杂系统的可靠性和效率，最终导致更安全、更有效的操作。随着技术的不断进步，准确定义和遵循这些限制的重要性只会增加，这强调了在这一领域持续研究和发展的必要性。