selective control system

简明释义

选择控制系统

英英释义

例句

1.A selective control system can improve energy efficiency in smart buildings by controlling lighting and HVAC systems.

选择性控制系统可以通过控制照明和暖通空调系统提高智能建筑的能效。

2.The gaming console features a selective control system that adjusts settings based on player preferences.

这款游戏主机配备了一个选择性控制系统，根据玩家偏好调整设置。

3.In robotics, a selective control system allows for precise manipulation of multiple joints.

在机器人技术中，选择性控制系统允许对多个关节进行精确操作。

4.The new aircraft utilizes a selective control system to enhance stability during flight.

新型飞机采用了选择性控制系统以增强飞行稳定性。

5.The factory's automation relies on a selective control system to manage different production lines efficiently.

工厂的自动化依赖于选择性控制系统以高效管理不同的生产线。

作文

In the realm of engineering and technology, the concept of a selective control system plays a pivotal role in enhancing efficiency and precision. A selective control system is designed to manage and regulate specific processes while ignoring others that may not be relevant at the moment. This selective approach allows for optimized performance in various applications, from industrial automation to advanced robotics. One of the most significant advantages of a selective control system is its ability to improve resource allocation. In manufacturing environments, for instance, a selective control system can prioritize tasks based on their urgency and importance. By focusing on high-priority tasks, the system ensures that resources such as time, labor, and materials are utilized effectively. This not only increases productivity but also reduces waste, contributing to more sustainable practices in production. Moreover, the implementation of a selective control system can enhance safety in various operations. In hazardous environments, such as chemical plants or construction sites, a selective control system can monitor critical parameters and trigger alarms or shutdowns if certain thresholds are exceeded. This selective monitoring helps prevent accidents and ensures the safety of personnel and equipment. Additionally, a selective control system enables better data management and analysis. By filtering out irrelevant information, the system can focus on key metrics that drive decision-making. For example, in data centers, a selective control system can analyze traffic patterns and allocate bandwidth accordingly, ensuring optimal performance for critical applications while minimizing latency for less important tasks. The versatility of a selective control system extends to various fields, including telecommunications, automotive engineering, and aerospace. In telecommunications, for instance, a selective control system can manage network traffic by prioritizing calls and data transmissions based on user needs and service level agreements. In the automotive industry, these systems can control engine functions selectively to enhance fuel efficiency and reduce emissions. Similarly, in aerospace, a selective control system can manage flight operations, ensuring that essential systems are prioritized during critical phases of flight. However, implementing a selective control system is not without challenges. The complexity of designing such systems requires a deep understanding of both the processes involved and the technology used. Engineers must ensure that the selective control system is capable of accurately distinguishing between relevant and irrelevant data. Furthermore, there is a need for continuous updates and maintenance to adapt to changing conditions and requirements. In conclusion, the selective control system is a crucial component in modern engineering, offering numerous benefits across different industries. Its ability to enhance efficiency, improve safety, and facilitate better data management makes it an invaluable tool in today's fast-paced technological landscape. As industries continue to evolve, the importance of selective control systems will only grow, paving the way for more innovative solutions and practices. Understanding and mastering this concept will undoubtedly be beneficial for future engineers and technologists who aspire to contribute to the advancement of their fields.

在工程和技术领域，选择性控制系统的概念在提高效率和精确度方面发挥着关键作用。选择性控制系统旨在管理和调节特定的过程，同时忽略那些可能在此时不相关的其他过程。这种选择性的方法使得在各种应用中优化性能成为可能，从工业自动化到先进的机器人技术。选择性控制系统的一个重要优势是它能够改善资源分配。例如，在制造环境中，选择性控制系统可以根据任务的紧急性和重要性来优先处理任务。通过专注于高优先级任务，该系统确保时间、劳动力和材料等资源得到有效利用。这不仅提高了生产力，还减少了浪费，有助于在生产中采取更可持续的做法。此外，实施选择性控制系统可以提高各种操作的安全性。在危险环境中，例如化工厂或建筑工地，选择性控制系统可以监控关键参数，并在某些阈值被超越时触发警报或停机。这种选择性监控有助于防止事故，并确保人员和设备的安全。此外，选择性控制系统使得更好的数据管理和分析成为可能。通过过滤掉不相关的信息，系统可以专注于驱动决策的关键指标。例如，在数据中心，选择性控制系统可以分析流量模式并相应地分配带宽，确保关键应用的最佳性能，同时最小化不太重要任务的延迟。选择性控制系统的多功能性延伸到电信、汽车工程和航空航天等多个领域。例如，在电信中，选择性控制系统可以通过根据用户需求和服务水平协议优先处理电话和数据传输来管理网络流量。在汽车行业，这些系统可以选择性地控制发动机功能，以提高燃油效率并减少排放。同样，在航空航天中，选择性控制系统可以管理飞行操作，确保在飞行的关键阶段优先处理必要系统。然而，实施选择性控制系统并非没有挑战。设计这种系统的复杂性需要对所涉及的过程和所使用的技术有深入的理解。工程师必须确保选择性控制系统能够准确区分相关和不相关的数据。此外，需要持续更新和维护，以适应变化的条件和要求。总之，选择性控制系统是现代工程中的一个关键组成部分，在不同的行业中提供了众多好处。它提高效率、改善安全性和促进更好的数据管理的能力，使其成为当今快节奏技术环境中不可或缺的工具。随着行业的不断发展，选择性控制系统的重要性只会增加，为更创新的解决方案和实践铺平道路。理解和掌握这一概念无疑将对未来的工程师和技术人员有所裨益，他们希望为自己领域的进步作出贡献。