maximum cross adjustment

简明释义

最大横向调整表

英英释义

例句

1.During the meeting, we discussed the maximum cross adjustment 最大交叉调整 required for the project to meet safety standards.

在会议上，我们讨论了项目为满足安全标准所需的最大交叉调整。

2.For optimal performance, the team recommended a maximum cross adjustment 最大交叉调整 of the system parameters.

为了获得最佳性能，团队建议对系统参数进行最大交叉调整。

3.The research indicated that a maximum cross adjustment 最大交叉调整 could enhance the efficiency of the energy grid.

研究表明，最大交叉调整可以提高能源网的效率。

4.The software update included a feature that allows for maximum cross adjustment 最大交叉调整 of user settings across multiple devices.

软件更新包括一个功能，允许对多个设备的用户设置进行最大交叉调整。

5.The engineer calculated the maximum cross adjustment 最大交叉调整 needed to stabilize the bridge under heavy winds.

工程师计算了在强风下稳定桥梁所需的最大交叉调整。

作文

In the realm of engineering and design, the concept of maximum cross adjustment plays a crucial role in ensuring that systems function efficiently and effectively. This term refers to the highest degree of modification or calibration that can be applied across different components of a system to achieve optimal performance. Understanding this concept is essential for engineers who aim to enhance the functionality of their designs while maintaining safety and reliability.To illustrate the significance of maximum cross adjustment, consider the example of an aircraft's control system. In aviation, precision is paramount; even the slightest deviation in control can lead to catastrophic outcomes. Engineers must account for various factors such as weight distribution, aerodynamic forces, and pilot input. By implementing maximum cross adjustment, they can fine-tune the interaction between different control surfaces, such as ailerons and elevators, to ensure that the aircraft responds predictably to pilot commands.Moreover, maximum cross adjustment is not limited to mechanical systems. It also applies to software development, where different modules must interact seamlessly. For instance, in a complex software application, adjustments may need to be made to the user interface, database interactions, and backend processes. The ability to perform maximum cross adjustment allows developers to optimize performance and enhance user experience by ensuring that all components work harmoniously together.The process of achieving maximum cross adjustment often involves rigorous testing and validation. Engineers and developers must simulate various scenarios to identify potential issues and make necessary adjustments. This iterative process is vital for uncovering hidden problems that may not be apparent during initial design phases. By embracing maximum cross adjustment, teams can proactively address these challenges, leading to more robust and reliable systems.Furthermore, the importance of maximum cross adjustment extends beyond technical applications. In project management, for example, leaders must adjust resources and timelines across different departments to ensure that a project stays on track. This requires a keen understanding of how changes in one area can impact others, necessitating a comprehensive approach to adjustments. By applying the principles of maximum cross adjustment, project managers can navigate complexities and drive successful outcomes.In conclusion, maximum cross adjustment is a vital concept in various fields, including engineering, software development, and project management. Its ability to enhance performance through precise calibration and modification makes it indispensable for creating efficient and reliable systems. As technology continues to evolve, the need for effective maximum cross adjustment will only grow, underscoring the importance of mastering this concept for professionals across disciplines. By prioritizing maximum cross adjustment, we can pave the way for innovations that improve our everyday lives and ensure the safety and efficiency of critical systems.

在工程和设计领域，最大交叉调整的概念在确保系统高效有效地运作中起着至关重要的作用。这个术语指的是可以应用于系统不同组件的最高修改或校准程度，以实现最佳性能。理解这一概念对于那些希望提高其设计功能的工程师至关重要，同时保持安全性和可靠性。为了说明最大交叉调整的重要性，可以考虑飞机控制系统的例子。在航空领域，精确是至关重要的；即使是最轻微的控制偏差也可能导致灾难性的后果。工程师必须考虑各种因素，如重量分布、空气动力学力和飞行员输入。通过实施最大交叉调整，他们可以微调不同控制面之间的相互作用，例如副翼和升降舵，以确保飞机对飞行员指令的反应可预测。此外，最大交叉调整并不限于机械系统。它同样适用于软件开发，其中不同模块必须无缝互动。例如，在复杂的软件应用程序中，可能需要对用户界面、数据库交互和后端处理进行调整。能够执行最大交叉调整允许开发人员优化性能并通过确保所有组件协同工作来增强用户体验。实现最大交叉调整的过程通常涉及严格的测试和验证。工程师和开发人员必须模拟各种场景，以识别潜在问题并进行必要的调整。这一迭代过程对于发现初始设计阶段可能不明显的隐藏问题至关重要。通过采用最大交叉调整，团队可以主动解决这些挑战，从而导致更强大和可靠的系统。此外，最大交叉调整的重要性超越了技术应用。在项目管理中，例如，领导者必须在不同部门之间调整资源和时间表，以确保项目按计划进行。这需要敏锐地理解一个领域的变化如何影响其他领域，因此需要全面的方法来进行调整。通过应用最大交叉调整的原则，项目经理可以驾驭复杂性并推动成功的结果。总之，最大交叉调整是各个领域的重要概念，包括工程、软件开发和项目管理。它通过精确的校准和修改来增强性能，使其成为创建高效和可靠系统不可或缺的工具。随着技术的不断发展，对有效的最大交叉调整的需求只会增加，这突显出掌握这一概念对于各学科专业人士的重要性。通过优先考虑最大交叉调整，我们可以为改善日常生活和确保关键系统的安全与效率铺平道路。