steady-state performance

简明释义

稳态特性

英英释义

例句

1.In order to improve the steady-state performance of the system, we need to optimize the control algorithms.

为了提高系统的稳态性能，我们需要优化控制算法。

2.We analyzed the steady-state performance of the heating system to ensure it meets safety standards.

我们分析了供热系统的稳态性能以确保其符合安全标准。

3.The steady-state performance of this circuit is crucial for ensuring reliable operation in long-term applications.

该电路的稳态性能对于确保长期应用中的可靠运行至关重要。

4.The engineer conducted tests to measure the steady-state performance of the motor under various loads.

工程师进行了测试，以测量电机在不同负载下的稳态性能。

5.A thorough understanding of steady-state performance can help in diagnosing issues in complex systems.

对稳态性能的透彻理解可以帮助诊断复杂系统中的问题。

作文

In the world of engineering and system design, the term steady-state performance refers to the behavior of a system when it has reached a stable condition after undergoing initial changes. This concept is crucial in various fields, including control systems, electronics, and mechanical engineering. Understanding steady-state performance is essential for engineers and designers as it allows them to predict how systems will behave under normal operating conditions, ensuring reliability and efficiency.To illustrate the importance of steady-state performance, consider a simple heating system in a home. When the heating system is turned on, it does not immediately reach the desired temperature. Instead, it goes through a period of adjustment where the temperature gradually increases. Once the system has been running for an adequate amount of time, it reaches a point where the temperature stabilizes at the set level. This stable state is what we refer to as steady-state performance. At this point, the system operates efficiently, maintaining the desired temperature without excessive energy consumption or fluctuations.The analysis of steady-state performance often involves examining key parameters such as response time, stability, and efficiency. For example, in a control system designed to maintain a specific temperature, engineers will assess how quickly the system can reach the desired temperature and how well it can maintain that temperature over time. This analysis helps identify potential issues that may arise during operation, allowing for adjustments to be made in the design phase.Moreover, steady-state performance is not limited to thermal systems; it is also applicable in electrical circuits. In an electrical circuit, when a voltage is applied, the current does not instantly reach its final value. Instead, it takes some time to stabilize, during which the circuit may experience transient behaviors. Once the current stabilizes, the circuit exhibits its steady-state performance, characterized by constant voltage and current levels. Engineers must understand these dynamics to design circuits that function reliably under varying conditions.In addition to practical applications, the concept of steady-state performance is vital in theoretical studies. Researchers often use mathematical models to predict how systems will behave over time. These models help in understanding the limits of a system’s performance and identifying areas for improvement. For instance, in the field of telecommunications, understanding the steady-state performance of a network can help in optimizing data transmission rates and minimizing delays.In conclusion, steady-state performance is a fundamental concept in engineering and system design that describes the stable behavior of a system after initial disturbances. Whether in heating systems, electrical circuits, or complex networks, understanding this concept allows engineers to design more efficient and reliable systems. By focusing on steady-state performance, we can ensure that systems operate effectively under normal conditions, ultimately leading to better performance and user satisfaction.

在工程和系统设计的世界中，术语steady-state performance指的是一个系统在经历初始变化后达到稳定状态时的行为。这个概念在控制系统、电子学和机械工程等多个领域至关重要。理解steady-state performance对工程师和设计师来说是必不可少的，因为它使他们能够预测系统在正常操作条件下的行为，从而确保可靠性和效率。为了说明steady-state performance的重要性，考虑一个简单的家庭供暖系统。当供暖系统开启时，它不会立即达到所需的温度。相反，它会经历一个调整期，在这个过程中温度逐渐升高。一旦系统运行到足够的时间，它就会达到一个点，此时温度稳定在设定水平。这个稳定状态就是我们所称的steady-state performance。在这一点上，系统高效运行，维持所需的温度，而不会过度消耗能源或出现波动。对steady-state performance的分析通常涉及关键参数，如响应时间、稳定性和效率。例如，在一个旨在维持特定温度的控制系统中，工程师将评估系统达到所需温度的速度以及在一段时间内保持该温度的能力。这种分析帮助识别在操作过程中可能出现的问题，从而在设计阶段进行调整。此外，steady-state performance不仅限于热系统；它在电路中也适用。在电路中，当施加电压时，电流不会立即达到其最终值。相反，它需要一些时间来稳定，在此期间电路可能会经历瞬态行为。一旦电流稳定，电路就会表现出其steady-state performance，特征为恒定的电压和电流水平。工程师必须理解这些动态，以设计在不同条件下可靠运行的电路。除了实际应用外，steady-state performance的概念在理论研究中也至关重要。研究人员经常使用数学模型来预测系统随时间的行为。这些模型有助于理解系统性能的极限并识别改进的领域。例如，在电信领域，理解网络的steady-state performance可以帮助优化数据传输速率并最小化延迟。总之，steady-state performance是工程和系统设计中的一个基本概念，描述了一个系统在初始干扰后稳定的行为。无论是在供暖系统、电路还是复杂网络中，理解这一概念使工程师能够设计出更高效、更可靠的系统。通过关注steady-state performance，我们可以确保系统在正常条件下有效运行，最终提高性能和用户满意度。