sensitivity-time control

简明释义

灵敏度-时间控制

英英释义

例句

1.In the field of audio engineering, sensitivity-time control 灵敏度-时间控制 is crucial for balancing sound levels.

在音频工程领域，sensitivity-time control 灵敏度-时间控制 对于平衡音量水平至关重要。

2.The new camera features advanced sensitivity-time control 灵敏度-时间控制 to capture high-quality images in low light.

这款新相机具备先进的sensitivity-time control 灵敏度-时间控制，能够在低光环境下拍摄高质量图像。

3.The drone's flight system incorporates sensitivity-time control 灵敏度-时间控制 to ensure stability during maneuvers.

无人机的飞行系统结合了sensitivity-time control 灵敏度-时间控制，以确保在机动期间的稳定性。

4.The software allows users to adjust sensitivity-time control 灵敏度-时间控制 settings for optimal performance.

该软件允许用户调整sensitivity-time control 灵敏度-时间控制设置，以获得最佳性能。

5.During the experiment, researchers utilized sensitivity-time control 灵敏度-时间控制 to measure reaction times accurately.

在实验过程中，研究人员利用sensitivity-time control 灵敏度-时间控制来准确测量反应时间。

作文

In the realm of technology and automation, the concept of sensitivity-time control plays a crucial role in ensuring that systems respond appropriately to various stimuli over time. This term refers to the ability of a system to adjust its responses based on the sensitivity to changes in environmental conditions while also considering the timing of these changes. Understanding sensitivity-time control is essential for engineers and designers who aim to create efficient and responsive systems.To illustrate the importance of sensitivity-time control, let's consider an example from the field of robotics. Imagine a robotic arm designed to perform delicate tasks, such as assembling electronic components. The arm must be sensitive enough to detect the slightest variations in pressure when gripping an object. If the arm applies too much force, it could damage the component. Conversely, if it applies too little force, the component might slip out of its grasp. Here, sensitivity-time control ensures that the robotic arm adjusts its grip based on real-time feedback, allowing it to operate effectively without damaging the components it handles.Moreover, sensitivity-time control is not limited to robotics; it is also prevalent in various other fields, such as environmental monitoring and healthcare. For instance, in environmental science, sensors that monitor air quality must be sensitive to changes in pollutant levels. If a sensor detects a spike in pollution, it must relay that information quickly to initiate appropriate responses, such as alerts or automated systems to mitigate the pollution. The timing of these responses is critical, emphasizing the need for effective sensitivity-time control.In healthcare, consider the use of wearable devices that monitor vital signs. These devices must be sensitive enough to detect fluctuations in heart rate or blood pressure. If a significant change occurs, the device must notify the user or healthcare providers promptly. Here, sensitivity-time control ensures that individuals receive timely interventions, which can be lifesaving.The integration of sensitivity-time control into various technological systems highlights the ongoing evolution of automation and control systems. With advancements in artificial intelligence and machine learning, systems are becoming increasingly adept at processing vast amounts of data and making real-time decisions based on sensitivity and timing. This evolution promises to enhance the efficiency and effectiveness of systems across multiple domains.In conclusion, sensitivity-time control is a fundamental concept that underscores the importance of responsive and adaptive systems in technology. Its applications span robotics, environmental monitoring, and healthcare, demonstrating its versatility and significance. As technology continues to advance, the principles of sensitivity-time control will remain integral to developing systems that can react intelligently and promptly to their environments, ultimately leading to improved outcomes and efficiencies in various industries.

在技术和自动化领域，sensitivity-time control（灵敏度-时间控制）的概念在确保系统适当地响应各种刺激方面发挥着至关重要的作用。这个术语指的是系统根据对环境条件变化的灵敏度调整其响应的能力，同时考虑这些变化的时间。理解sensitivity-time control对于工程师和设计师来说至关重要，他们旨在创建高效且响应迅速的系统。为了说明sensitivity-time control的重要性，让我们考虑一个来自机器人领域的例子。想象一下，一个设计用于执行精细任务的机器人手臂，比如组装电子元件。手臂必须足够灵敏，以便在抓取物体时检测到最轻微的压力变化。如果手臂施加过大的力量，可能会损坏组件。相反，如果施加的力量太小，组件可能会滑出它的抓握。在这里，sensitivity-time control确保机器人手臂根据实时反馈调整其抓握，从而有效地操作，而不会损坏其处理的组件。此外，sensitivity-time control不仅限于机器人；它在环境监测和医疗等多个领域也很普遍。例如，在环境科学中，监测空气质量的传感器必须对污染物水平的变化敏感。如果传感器检测到污染的激增，它必须迅速传递该信息，以启动适当的响应，例如警报或自动化系统来减轻污染。响应的时机至关重要，这强调了有效的sensitivity-time control的必要性。在医疗保健中，考虑使用监测生命体征的可穿戴设备。这些设备必须足够灵敏，以检测心率或血压的波动。如果发生显著变化，设备必须及时通知用户或医疗提供者。在这里，sensitivity-time control确保个人获得及时干预，这可能是挽救生命的。将sensitivity-time control集成到各种技术系统中突显了自动化和控制系统的持续演变。随着人工智能和机器学习的进步，系统在处理大量数据和基于灵敏度和时机做出实时决策方面变得越来越擅长。这一演变有望提高多个领域系统的效率和有效性。总之，sensitivity-time control是一个基本概念，强调了技术中响应和自适应系统的重要性。它的应用跨越机器人、环境监测和医疗，展示了其多功能性和重要性。随着技术的不断进步，sensitivity-time control的原则将继续在开发能够智能和及时响应其环境的系统中发挥核心作用，最终导致各行业的结果和效率的改善。