stability parameter

简明释义

稳定性参数

英英释义

例句

1.The stability parameter is essential for ensuring the safety of the structure.

确保结构安全的稳定性参数是至关重要的。

2.A higher stability parameter can lead to more reliable results in data analysis.

更高的稳定性参数可以在数据分析中导致更可靠的结果。

3.In our simulation, the stability parameter played a crucial role in determining the outcome.

在我们的模拟中，稳定性参数在决定结果方面发挥了关键作用。

4.Researchers found that adjusting the stability parameter improved the model's accuracy.

研究人员发现，调整稳定性参数提高了模型的准确性。

5.The engineer adjusted the stability parameter to improve the system's performance.

工程师调整了稳定性参数以提高系统性能。

作文

In the field of engineering and systems analysis, the term stability parameter refers to a specific value or set of values that determine the stability of a system under various conditions. Stability is crucial in ensuring that systems behave predictably and do not exhibit erratic or uncontrolled behavior. For example, in control systems, the stability parameter can be related to factors such as feedback loops, gain margins, and phase margins. Engineers must carefully analyze these parameters to ensure that the system will remain stable over time, especially when subjected to external disturbances or changes in input. One of the key aspects of understanding the stability parameter is recognizing its role in dynamic systems. A dynamic system, such as an aircraft or a robotic arm, must maintain its equilibrium to perform effectively. The stability parameter helps in assessing how the system responds to changes in conditions, such as variations in load or environmental factors. If a system's stability parameter indicates potential instability, engineers may need to redesign components or implement control strategies to mitigate risks. Moreover, the concept of the stability parameter is not limited to engineering alone; it also extends into economics, ecology, and other fields. For instance, in economics, a market's stability parameter could refer to indicators like inflation rates or employment levels that impact overall economic stability. Similarly, in ecology, the stability parameter might relate to biodiversity levels or ecosystem resilience against disturbances. Understanding these parameters can provide insights into how systems can be managed or improved for better stability. To illustrate the importance of the stability parameter, consider the case of an aircraft during flight. The aircraft’s design incorporates various stability parameters such as center of gravity, wing shape, and tail configuration. These parameters are meticulously calculated and tested to ensure that the aircraft can respond appropriately to pilot inputs and environmental conditions. If any of these stability parameters are off, the aircraft could become difficult to control, leading to potential accidents. Thus, maintaining proper stability parameters is essential for safe and efficient flight operations. In conclusion, the stability parameter serves as a critical measure across diverse fields, playing a vital role in assessing and ensuring the stability of various systems. Whether in engineering, economics, or ecology, understanding and managing these parameters is essential for achieving desired outcomes and preventing failures. As technology advances and systems become increasingly complex, the significance of the stability parameter will only grow, highlighting the need for ongoing research and innovation in this area.

在工程和系统分析领域，术语稳定性参数指的是一组特定的值，这些值决定了系统在各种条件下的稳定性。稳定性对于确保系统行为可预测并且不会表现出不稳定或失控的行为至关重要。例如，在控制系统中，稳定性参数可能与反馈回路、增益裕度和相位裕度等因素相关。工程师必须仔细分析这些参数，以确保系统在时间的推移中保持稳定，特别是在受到外部干扰或输入变化时。理解稳定性参数的一个关键方面是认识到它在动态系统中的作用。动态系统，例如飞机或机械臂，必须保持其平衡以有效执行任务。稳定性参数有助于评估系统如何应对条件变化，例如负载变化或环境因素。如果系统的稳定性参数表明潜在的不稳定性，工程师可能需要重新设计组件或实施控制策略以减轻风险。此外，稳定性参数的概念不仅限于工程，它也延伸到经济学、生态学和其他领域。例如，在经济学中，市场的稳定性参数可能指影响整体经济稳定性的指标，如通货膨胀率或就业水平。同样，在生态学中，稳定性参数可能与生物多样性水平或生态系统抵御干扰的韧性有关。理解这些参数可以提供关于如何管理或改善系统以实现更好稳定性的见解。为了说明稳定性参数的重要性，考虑飞机在飞行过程中的案例。飞机的设计包含各种稳定性参数，例如重心、机翼形状和尾部配置。这些参数经过精确计算和测试，以确保飞机能够适当地响应飞行员的输入和环境条件。如果这些稳定性参数中的任何一个不正确，飞机可能会变得难以控制，导致潜在的事故。因此，保持适当的稳定性参数对于安全和高效的飞行操作至关重要。总之，稳定性参数作为跨多个领域的关键测量，发挥着评估和确保各种系统稳定性的至关重要的作用。无论是在工程、经济学还是生态学中，理解和管理这些参数对于实现预期结果和防止失败至关重要。随着技术的发展和系统变得越来越复杂，稳定性参数的重要性只会增加，突显出在这一领域持续研究和创新的必要性。