driving oscillator

简明释义

主控振荡器

英英释义

例句

1.In radio transmitters, the driving oscillator generates the carrier wave needed for broadcasting.

在无线电发射器中，驱动振荡器产生广播所需的载波。

2.Engineers often use a driving oscillator to test the response of various components in a system.

工程师们常常使用驱动振荡器来测试系统中各种组件的响应。

3.A stable driving oscillator is crucial for ensuring accurate timing in digital circuits.

稳定的驱动振荡器对于确保数字电路中的准确计时至关重要。

4.The performance of the driving oscillator directly affects the quality of the output signal.

驱动振荡器的性能直接影响输出信号的质量。

5.The driving oscillator in the circuit maintains a consistent frequency for signal transmission.

电路中的驱动振荡器保持信号传输的一致频率。

作文

In the realm of physics and engineering, oscillators play a crucial role in various applications, from clocks to radio transmitters. One particular type of oscillator that is essential for many systems is the driving oscillator. A driving oscillator refers to an oscillator that provides a periodic signal to drive another system or component, enabling it to operate at a specific frequency. This concept is fundamental in understanding how different systems synchronize and interact with each other.To grasp the significance of a driving oscillator, one must first understand what an oscillator is. An oscillator is a device or circuit that produces a repetitive signal, often in the form of a sine wave or square wave. These signals are used in various applications, such as generating clock pulses in digital circuits or producing sound waves in audio equipment. Oscillators can be classified into different types based on their characteristics and applications, including harmonic oscillators, relaxation oscillators, and more.The driving oscillator is particularly important in systems where synchronization is key. For instance, in communication systems, a driving oscillator can be used to modulate a carrier wave, allowing information to be transmitted over long distances. The accuracy and stability of the signal produced by the driving oscillator directly impact the quality of the communication, making it a vital component in these systems.Additionally, in mechanical systems, a driving oscillator can be employed to induce vibrations in structures or materials. This principle is often utilized in testing the durability of components, where a driving oscillator creates controlled vibrations to simulate real-world conditions. By analyzing how the material responds to these vibrations, engineers can determine its strength and reliability.The concept of a driving oscillator also extends to biological systems. For example, in the study of circadian rhythms, researchers have found that certain biological processes are regulated by oscillatory signals. In this context, a driving oscillator can refer to external factors, such as light or temperature changes, that influence the internal biological clocks of organisms. Understanding these interactions helps scientists develop better strategies for managing health and wellness.In conclusion, the driving oscillator is a fundamental concept that underpins many scientific and engineering disciplines. Its ability to provide a stable and periodic signal makes it indispensable in applications ranging from telecommunications to mechanical testing and biological research. As technology continues to advance, the role of driving oscillators will likely expand, leading to new innovations and discoveries in various fields. Therefore, a thorough understanding of the driving oscillator and its applications is essential for anyone looking to delve deeper into the world of oscillatory systems and their impact on our daily lives.

在物理和工程领域，振荡器在各种应用中发挥着至关重要的作用，从时钟到无线电发射器。其中一种对许多系统至关重要的振荡器是驱动振荡器。驱动振荡器指的是提供周期性信号以驱动另一个系统或组件的振荡器，使其能够以特定频率运行。这个概念对于理解不同系统如何同步和相互作用至关重要。要理解驱动振荡器的重要性，首先必须了解振荡器是什么。振荡器是产生重复信号的设备或电路，通常以正弦波或方波的形式出现。这些信号用于各种应用，例如在数字电路中生成时钟脉冲或在音频设备中产生声波。振荡器可以根据其特征和应用分类为不同类型，包括谐振荡器、放松振荡器等。驱动振荡器在需要同步的系统中尤为重要。例如，在通信系统中，可以使用驱动振荡器调制载波波形，从而使信息能够远距离传输。驱动振荡器产生的信号的准确性和稳定性直接影响通信质量，使其成为这些系统中的关键组件。此外，在机械系统中，可以利用驱动振荡器在结构或材料中诱导振动。这一原理常用于测试组件的耐久性，其中驱动振荡器产生控制振动，以模拟现实条件。通过分析材料如何响应这些振动，工程师可以确定其强度和可靠性。驱动振荡器的概念还扩展到生物系统。例如，在昼夜节律的研究中，研究人员发现某些生物过程受到振荡信号的调节。在这种情况下，驱动振荡器可以指影响有机体内部生物钟的外部因素，如光照或温度变化。理解这些相互作用有助于科学家制定更好的健康和保健管理策略。总之，驱动振荡器是支撑许多科学和工程学科的基本概念。它提供稳定和周期性信号的能力使其在从电信到机械测试和生物研究等应用中不可或缺。随着技术的不断进步，驱动振荡器的作用可能会扩大，导致各个领域的新创新和发现。因此，深入理解驱动振荡器及其应用对于任何希望深入研究振荡系统及其对我们日常生活影响的人来说都是至关重要的。