operating characteristic

简明释义

工作特性

英英释义

例句

1.The operating characteristic of this machine allows it to function under extreme conditions.

这台机器的操作特性使其能够在极端条件下运行。

2.The engineer analyzed the system's operating characteristic to determine its efficiency.

工程师分析了系统的操作特性以确定其效率。

3.We need to document the operating characteristic of our product for compliance purposes.

我们需要记录我们产品的操作特性以满足合规要求。

4.The team conducted tests to evaluate the operating characteristic of the new battery.

团队进行了测试以评估新电池的操作特性。

5.Understanding the operating characteristic of the new software is crucial for its successful deployment.

理解新软件的操作特性对其成功部署至关重要。

作文

In the field of engineering and systems analysis, understanding the operating characteristic of a system is crucial for its design and implementation. The term operating characteristic refers to the performance attributes of a system when it is functioning under specific conditions. These characteristics can include various parameters such as efficiency, reliability, capacity, and response time. By analyzing these factors, engineers can determine how well a system will perform in real-world scenarios and make necessary adjustments to optimize its functionality.For instance, consider a manufacturing plant that utilizes robotic arms for assembly. The operating characteristic of these robotic arms would include their speed of operation, precision in handling components, and the maximum load they can bear. By studying these characteristics, managers can identify potential bottlenecks in production and implement solutions to enhance overall efficiency.Moreover, the operating characteristic is not limited to mechanical systems; it also applies to software applications. In software development, understanding the operating characteristic of an application involves assessing its processing speed, user interface responsiveness, and ability to handle multiple tasks simultaneously. Developers conduct performance testing to gather data on these aspects, ensuring that the application meets user expectations and functions smoothly under varying loads.In addition to engineering and software applications, the concept of operating characteristic is also vital in the realm of quality control and testing. For example, in statistical process control, the operating characteristic curve is used to illustrate the relationship between the probability of detecting a defect and the actual quality level of a product. This curve helps quality assurance teams understand the effectiveness of their inspection processes and make informed decisions about production quality.Furthermore, understanding the operating characteristic of a system can aid in risk management. By identifying the limits of performance and potential failure points, organizations can develop contingency plans to mitigate risks associated with system failures. This proactive approach not only enhances safety but also improves overall operational resilience.In conclusion, the operating characteristic of any system—be it mechanical, software, or procedural—is a fundamental aspect that dictates its performance and reliability. Engineers, developers, and quality control professionals must thoroughly analyze these characteristics to ensure optimal functionality and quality. As industries continue to evolve and integrate advanced technologies, the importance of understanding operating characteristic will only grow, driving innovation and efficiency in various sectors. Therefore, investing time and resources into comprehensively studying the operating characteristic of systems is essential for achieving success in today’s competitive landscape.

在工程和系统分析领域，理解一个系统的操作特性对于其设计和实施至关重要。术语操作特性指的是系统在特定条件下运行时的性能属性。这些特性可以包括各种参数，例如效率、可靠性、容量和响应时间。通过分析这些因素，工程师可以确定一个系统在现实场景中的表现如何，并进行必要的调整以优化其功能。例如，考虑一个利用机器人臂进行组装的制造工厂。这些机器人臂的操作特性将包括它们的操作速度、处理组件的精度和它们能够承受的最大负载。通过研究这些特性，管理者可以识别生产中的潜在瓶颈，并实施解决方案以提高整体效率。此外，操作特性不仅限于机械系统；它也适用于软件应用程序。在软件开发中，理解应用程序的操作特性涉及评估其处理速度、用户界面响应能力以及同时处理多个任务的能力。开发人员进行性能测试以收集这些方面的数据，确保应用程序符合用户期望并在不同负载下平稳运行。除了工程和软件应用，操作特性的概念在质量控制和测试领域也至关重要。例如，在统计过程控制中，操作特性曲线用于说明检测缺陷的概率与产品实际质量水平之间的关系。这条曲线帮助质量保证团队了解其检查过程的有效性，并就生产质量做出明智的决策。此外，理解一个系统的操作特性可以帮助风险管理。通过识别性能的极限和潜在的故障点，组织可以制定应急计划，以减轻与系统故障相关的风险。这种主动的方法不仅增强了安全性，还提高了整体操作的韧性。总之，任何系统的操作特性——无论是机械的、软件的还是程序性的——都是决定其性能和可靠性的基本方面。工程师、开发人员和质量控制专业人员必须彻底分析这些特性，以确保最佳功能和质量。随着各行业不断发展并整合先进技术，理解操作特性的重要性只会增加，推动各个部门的创新和效率。因此，投入时间和资源全面研究系统的操作特性对于在当今竞争激烈的环境中取得成功至关重要。