detection of oscillation

简明释义

检波

英英释义

例句

1.The detection of oscillation in the electrical circuit was crucial for troubleshooting.

电路中的振荡检测对于故障排除至关重要。

2.Engineers use the detection of oscillation to monitor the health of machinery.

工程师使用振荡检测来监测机器的健康状况。

3.In the lab, we focus on the detection of oscillation in fluid dynamics experiments.

在实验室，我们专注于流体动力学实验中的振荡检测。

4.The detection of oscillation in the signal indicates a potential fault in the system.

信号中的振荡检测表明系统可能存在故障。

5.The detection of oscillation can help identify resonant frequencies in structures.

振荡检测可以帮助识别结构中的共振频率。

作文

The concept of detection of oscillation plays a crucial role in various fields such as engineering, physics, and even biology. Oscillation refers to the repetitive variation, typically in time, of some measure about a central value or between two or more different states. In simpler terms, it can be seen as a back-and-forth movement or fluctuation. The detection of oscillation involves identifying these variations and understanding their patterns, which can provide valuable insights into the systems being studied.In engineering, for instance, the detection of oscillation is vital for monitoring the integrity of structures such as bridges and buildings. Engineers use sensors to detect vibrations that may indicate structural weaknesses. If an oscillation is detected beyond a certain threshold, it could signal potential failure or the need for maintenance. This proactive approach not only ensures safety but also extends the lifespan of the infrastructure.In the realm of physics, detection of oscillation is essential in studying waves and vibrations. Whether it’s sound waves, electromagnetic waves, or mechanical vibrations, understanding oscillations helps physicists develop theories and applications that can lead to technological advancements. For example, the detection of oscillatory patterns in light waves has led to the development of lasers, which have numerous applications ranging from medical devices to telecommunications.Biologists also utilize the detection of oscillation in their research. Many biological processes exhibit oscillatory behavior, such as circadian rhythms, which are the natural cycles that regulate sleep and wakefulness in living organisms. By detecting these oscillations, scientists can gain insights into how organisms adapt to their environments, how they respond to changes, and even how diseases can disrupt these natural rhythms. For instance, disruptions in circadian oscillations have been linked to various health issues, including sleep disorders and metabolic syndromes.Moreover, the detection of oscillation is not limited to scientific fields; it has practical implications in everyday life. For example, in audio engineering, the detection of oscillation in sound waves allows sound engineers to enhance audio quality by eliminating unwanted noise or feedback. Similarly, in finance, oscillatory patterns in stock prices can help traders make informed decisions based on market trends.In conclusion, the detection of oscillation is a fundamental process that permeates various disciplines. Its significance lies in its ability to provide insights, ensure safety, and drive innovation. As technology advances, the methods and tools for detecting oscillations continue to improve, leading to even greater understanding and control over the systems we interact with. Embracing this concept allows us to better appreciate the complexities of the world around us and harness these insights for future advancements. Understanding the detection of oscillation not only enhances our knowledge across multiple domains but also empowers us to make informed decisions in both professional and personal contexts.

“振荡检测”的概念在工程、物理甚至生物等多个领域中发挥着至关重要的作用。振荡是指某种度量在中心值或两个或多个不同状态之间的重复变化，通常是随时间而变化的。简单来说，它可以被视为一种前后移动或波动。“振荡检测”涉及识别这些变化并理解它们的模式，这可以为所研究的系统提供有价值的见解。例如，在工程领域，“振荡检测”对于监测桥梁和建筑物等结构的完整性至关重要。工程师使用传感器来检测可能表明结构弱点的振动。如果检测到的振荡超过某个阈值，可能会发出潜在故障或需要维护的信号。这种主动的方法不仅确保了安全性，还延长了基础设施的使用寿命。在物理学领域，“振荡检测”在研究波动和振动方面至关重要。无论是声波、电磁波还是机械振动，理解振荡有助于物理学家开发理论和应用，从而推动技术进步。例如，光波中的振荡模式的检测导致了激光的发展，激光在医疗设备和电信等多个应用中具有重要意义。生物学家也在他们的研究中利用“振荡检测”。许多生物过程表现出振荡行为，例如昼夜节律，即调节生物体睡眠和觉醒的自然周期。通过检测这些振荡，科学家可以深入了解生物体如何适应环境、如何应对变化，甚至如何疾病会扰乱这些自然节律。例如，昼夜节律的干扰与各种健康问题（包括睡眠障碍和代谢综合症）有关。此外，“振荡检测”并不限于科学领域；它在日常生活中也具有实际意义。例如，在音频工程中，声音波的振荡检测使声音工程师能够通过消除不必要的噪音或反馈来提高音质。同样，在金融领域，股票价格的振荡模式可以帮助交易者根据市场趋势做出明智的决策。总之，“振荡检测”是一个渗透多个学科的基本过程。其重要性在于它能够提供见解、确保安全并推动创新。随着技术的进步，检测振荡的方法和工具不断改善，导致我们对所互动系统的理解和控制的进一步提升。接受这一概念使我们更好地欣赏周围世界的复杂性，并利用这些见解推动未来的进步。理解“振荡检测”不仅增强了我们在多个领域的知识，还使我们能够在专业和个人环境中做出明智的决策。