conditional stability

简明释义

条件稳定性

英英释义

例句

1.In control theory, conditional stability is crucial for maintaining system performance within desired limits.

在控制理论中，条件稳定性对于维持系统性能在期望范围内至关重要。

2.During simulations, we observed that the model only achieved conditional stability under specific initial conditions.

在模拟过程中，我们观察到模型仅在特定初始条件下实现了条件稳定性。

3.Engineers must analyze the conditional stability of the structure to prevent failures during extreme weather events.

工程师必须分析结构的条件稳定性，以防止在极端天气事件中发生故障。

4.The system exhibits conditional stability when specific parameters are adjusted, ensuring safe operations under certain conditions.

当特定参数调整时，系统表现出条件稳定性，确保在某些条件下安全运行。

5.The algorithm's conditional stability was tested under various input scenarios to ensure reliability.

该算法的条件稳定性在各种输入场景下进行了测试，以确保可靠性。

作文

In the realm of science and engineering, the concept of conditional stability plays a crucial role in understanding the behavior of systems under varying conditions. Conditional stability refers to the state where a system remains stable only within certain parameters or conditions. This means that while a system may exhibit stability when specific criteria are met, it can become unstable if those criteria are altered. Such a phenomenon is particularly evident in fields like control theory, structural engineering, and even climate science.For instance, consider a bridge designed to withstand certain loads and environmental factors. The bridge is said to possess conditional stability because it can support vehicles and pedestrians safely as long as the weight does not exceed its design limits and external conditions remain favorable. However, if an unusually heavy vehicle crosses the bridge or if there are extreme weather conditions, the bridge's stability could be compromised, leading to potential failure. This example illustrates how conditional stability is essential for engineers to consider during the design and analysis phases of construction.Moreover, in control systems, conditional stability is a fundamental aspect that engineers must address. A control system might function effectively under normal operating conditions but can become unstable if there are fluctuations in input or unexpected disturbances. For example, an autopilot system in an aircraft is designed to maintain stability during flight. However, if the aircraft encounters severe turbulence or mechanical failures, the system's conditional stability could be challenged. Thus, engineers must incorporate safeguards and design features that help maintain stability even under adverse conditions.In climate science, the concept of conditional stability can be observed in the behavior of ecosystems. Certain ecosystems thrive under specific climatic conditions, exhibiting stability in species populations and interactions. However, if these conditions change—due to climate change or human intervention—the ecosystem may lose its conditional stability, leading to shifts in biodiversity, species extinction, and other ecological consequences. Understanding these dynamics is vital for conservation efforts and sustainable management of natural resources.The implications of conditional stability extend beyond technical fields; they also resonate in everyday life. For instance, personal relationships can exhibit conditional stability. A friendship may flourish under specific circumstances, such as shared interests and mutual respect. However, if these conditions change—perhaps due to a disagreement or life changes—the stability of the relationship could be jeopardized. Recognizing the conditional stability of our social connections can help us navigate challenges and work towards maintaining healthy relationships.In conclusion, the notion of conditional stability encompasses a wide range of applications across various disciplines. Whether in engineering, ecology, or personal relationships, understanding the conditions that contribute to stability is crucial for predicting and managing potential risks. By acknowledging the importance of conditional stability, we can better prepare ourselves for the uncertainties that life presents, ensuring resilience and adaptability in the face of change.

在科学和工程领域，条件稳定性的概念在理解系统在不同条件下的行为中起着至关重要的作用。条件稳定性指的是系统仅在某些参数或条件下保持稳定的状态。这意味着，虽然系统在特定标准满足时表现出稳定性，但如果这些标准发生变化，它可能会变得不稳定。这种现象在控制理论、结构工程甚至气候科学等领域尤为明显。例如，考虑一座设计用来承受特定负荷和环境因素的桥。这座桥被称为具有条件稳定性，因为它可以安全地支持车辆和行人，只要重量不超过其设计极限，并且外部条件保持有利。然而，如果一辆异常重的车辆经过桥梁，或者出现极端天气条件，桥的稳定性可能会受到损害，导致潜在的失败。这个例子说明了在建筑设计和分析阶段，工程师必须考虑条件稳定性的重要性。此外，在控制系统中，条件稳定性是工程师必须解决的基本方面。一个控制系统在正常操作条件下可能有效工作，但如果输入波动或出现意外干扰，它可能会变得不稳定。例如，飞机的自动驾驶系统旨在在飞行中保持稳定。然而，如果飞机遇到严重的颠簸或机械故障，系统的条件稳定性可能会受到挑战。因此，工程师必须纳入保障措施和设计特征，以帮助在不利条件下维持稳定。在气候科学中，条件稳定性的概念可以在生态系统的行为中观察到。某些生态系统在特定气候条件下繁荣，表现出物种种群和相互作用的稳定性。然而，如果这些条件发生变化——由于气候变化或人为干预——生态系统可能会失去其条件稳定性，导致生物多样性的变化、物种灭绝和其他生态后果。理解这些动态对保护工作和自然资源的可持续管理至关重要。条件稳定性的影响不仅限于技术领域；它们在日常生活中也产生共鸣。例如，人际关系可以表现出条件稳定性。一段友谊可能在特定情况下蓬勃发展，例如共同的兴趣和相互尊重。然而，如果这些条件发生变化——可能是由于分歧或生活变化——关系的稳定性可能会受到威胁。认识到我们社会联系的条件稳定性可以帮助我们应对挑战并努力维持健康的关系。总之，条件稳定性的概念涵盖了各个学科中的广泛应用。无论是在工程、生态学还是人际关系中，理解有助于稳定的条件对于预测和管理潜在风险至关重要。通过承认条件稳定性的重要性，我们可以更好地为生活中出现的不确定性做好准备，确保在变化面前的韧性和适应能力。