open oscillator

简明释义

敞式振子

英英释义

例句

1.The research team utilized an open oscillator for their quantum computing experiments.

研究小组在量子计算实验中利用了一个开放振荡器。

2.Using an open oscillator allows for greater flexibility in frequency modulation experiments.

使用开放振荡器可以在频率调制实验中提供更大的灵活性。

3.The engineer designed an open oscillator to generate stable waveforms for the audio system.

工程师设计了一个开放振荡器，用于为音频系统生成稳定的波形。

4.In radio transmission, an open oscillator helps create the necessary carrier waves.

在无线电传输中，开放振荡器帮助生成所需的载波波。

5.An open oscillator can be used in educational settings to demonstrate basic principles of electronics.

在教育环境中，可以使用开放振荡器来演示电子学的基本原理。

作文

In the realm of physics and engineering, the concept of an open oscillator is pivotal in understanding various dynamic systems. An open oscillator refers to a system that can oscillate freely without being confined to a closed loop. This characteristic allows for the exploration of its behavior under different external influences, making it a crucial topic in both theoretical and applied sciences.To grasp the significance of an open oscillator, we must first consider what oscillation means. Oscillation is the repetitive variation, typically in time, of some measure about a central value or between two or more different states. Common examples of oscillators include pendulums, springs, and electronic circuits. However, when we describe an oscillator as 'open', we imply that it interacts with its environment, leading to energy exchange and potentially influencing its oscillatory patterns.One of the most fascinating aspects of open oscillators is their application in real-world systems. For instance, in electronics, an open oscillator can be part of a radio transmitter, where it generates signals that are then sent out into space. The openness of the system allows it to modulate frequencies and transmit data over long distances. This principle is also evident in mechanical systems, such as a swing set. When a child swings, the swing acts as an open oscillator, influenced by the push from the child, air resistance, and gravitational forces.Moreover, open oscillators are essential in the study of chaos theory. In chaotic systems, small changes in initial conditions can lead to vastly different outcomes. An open oscillator can exhibit chaotic behavior when subjected to certain external forces or perturbations. This unpredictability is not only intriguing from a scientific standpoint but also has implications in fields such as meteorology and economics, where complex systems often behave in unforeseen ways.The concept of feedback is also integral to understanding open oscillators. Feedback occurs when a portion of the output of a system is fed back into the input. In an open oscillator, positive feedback can amplify oscillations, while negative feedback can dampen them. This interplay is vital in maintaining stability within various systems, whether they are natural ecosystems or engineered processes.Furthermore, research on open oscillators has led to advancements in technology. For example, scientists have been able to design more efficient energy systems by studying how open oscillators interact with their surroundings. This knowledge is crucial for developing sustainable technologies that minimize energy loss and maximize efficiency.In conclusion, the study of open oscillators offers valuable insights into the behavior of dynamic systems across multiple disciplines. By understanding how these systems operate and interact with their environments, we can develop better technologies, predict chaotic behaviors, and enhance our overall comprehension of the physical world. As we continue to explore the intricacies of open oscillators, we unlock new possibilities for innovation and discovery, paving the way for future advancements in science and engineering.

在物理和工程学领域，open oscillator的概念对于理解各种动态系统至关重要。open oscillator指的是一个可以自由振荡而不被限制在闭环中的系统。这一特性使得我们能够在不同的外部影响下探索其行为，使其成为理论和应用科学中的一个关键主题。要理解open oscillator的重要性，我们首先必须考虑什么是振荡。振荡是某种度量在时间上通常重复变化的过程，围绕中心值或在两个或多个不同状态之间进行变化。常见的振荡器包括摆、弹簧和电子电路。然而，当我们将振荡器描述为“开放”时，我们暗示它与环境相互作用，导致能量交换并可能影响其振荡模式。open oscillators最迷人的方面之一是它们在现实世界系统中的应用。例如，在电子学中，open oscillator可以是无线电发射器的一部分，它生成信号并将其发送到太空。该系统的开放性使其能够调制频率并远距离传输数据。这一原理在机械系统中也显而易见，例如秋千。当孩子在秋千上荡时，秋千作为一个open oscillator，受孩子的推动、空气阻力和重力的影响。此外，open oscillators在混沌理论的研究中也至关重要。在混沌系统中，初始条件的微小变化可以导致截然不同的结果。当受到某些外部力量或扰动的影响时，open oscillator可能会表现出混沌行为。这种不可预测性不仅从科学的角度令人着迷，而且在气象学和经济学等领域也有深远的影响，因为复杂系统往往以意想不到的方式运作。反馈的概念对于理解open oscillators也至关重要。反馈发生在系统的部分输出反馈到输入中。在open oscillator中，正反馈可以放大振荡，而负反馈可以减弱它们。这种相互作用在维持各种系统的稳定性方面至关重要，无论是自然生态系统还是工程过程。此外，对open oscillators的研究促进了技术的进步。例如，科学家通过研究open oscillators如何与周围环境相互作用，能够设计出更高效的能源系统。这一知识对于开发可持续技术至关重要，可以最大限度地减少能量损失并提高效率。总之，研究open oscillators为我们提供了关于多个学科动态系统行为的宝贵见解。通过理解这些系统如何运作以及如何与其环境相互作用，我们可以开发更好的技术，预测混沌行为，并增强我们对物理世界的整体理解。随着我们继续探索open oscillators的复杂性，我们为创新和发现开辟了新可能性，为未来科学和工程的进步铺平了道路。