transitron oscillator

简明释义

负跨导管振荡器

英英释义

例句

1.The transitron oscillator is crucial for generating stable frequencies in radar systems.

在雷达系统中，transitron oscillator对于生成稳定频率至关重要。

2.By using a transitron oscillator, we can achieve a more compact design for our electronic devices.

通过使用transitron oscillator，我们可以为电子设备实现更紧凑的设计。

3.In our latest project, we are implementing a transitron oscillator to improve the performance of our communication systems.

在我们最新的项目中，我们正在实施一个transitron oscillator以提高通信系统的性能。

4.Engineers often choose a transitron oscillator for its low phase noise characteristics in high-frequency applications.

工程师们通常选择transitron oscillator，因为它在高频应用中具有低相位噪声特性。

5.The design of the new radio transmitter incorporates a transitron oscillator, which enhances signal stability.

新型无线电发射器的设计中包含了一个transitron oscillator，这提高了信号的稳定性。

作文

The world of electronics is filled with fascinating devices that have revolutionized the way we communicate and process information. One such device is the transitron oscillator, a remarkable invention that has made significant contributions to the field of signal generation. Understanding the transitron oscillator requires delving into its components, functionality, and applications.At its core, a transitron oscillator is a type of electronic oscillator that utilizes a transitron, which is a specialized semiconductor device. This device is designed to produce oscillations at a specific frequency, making it ideal for various applications in communication systems, radio transmitters, and even in some types of computers. The transitron oscillator operates by converting direct current (DC) into an alternating current (AC) signal, allowing it to generate waveforms that can be used for transmitting data.The operation of a transitron oscillator is based on the principles of feedback and resonance. When power is supplied to the transitron, it enters a state where it can switch between conducting and non-conducting states. This switching action creates a feedback loop that sustains oscillations. The frequency of these oscillations can be finely tuned by adjusting various parameters within the circuit, such as resistance and capacitance. This tunability is one of the key advantages of the transitron oscillator, as it allows engineers to design circuits that can operate efficiently across a range of frequencies.In practical applications, the transitron oscillator has proven invaluable. For instance, in radio frequency (RF) applications, it is used to generate signals that can be transmitted over long distances. The ability to maintain a stable frequency makes it ideal for use in communication systems where clarity and consistency are crucial. Additionally, the transitron oscillator can be found in various consumer electronics, including televisions and radios, where it helps to ensure that signals are processed accurately.Moreover, the transitron oscillator has also played a role in the development of more advanced technologies. In the realm of digital computing, oscillators are essential for timing purposes. They help synchronize operations within the computer, ensuring that data is processed in a timely manner. As technology continues to advance, the principles behind the transitron oscillator are being applied to newer, more sophisticated devices that require precise control over frequency and timing.Despite its many advantages, the transitron oscillator is not without its challenges. For instance, maintaining stability in high-frequency applications can be difficult, and engineers must carefully design circuits to mitigate issues such as noise and signal distortion. Furthermore, as technology evolves, new types of oscillators are being developed that may offer better performance or efficiency compared to traditional transitron oscillators. Nevertheless, the foundational knowledge gained from understanding the transitron oscillator remains relevant and essential for anyone looking to explore the field of electronics.In conclusion, the transitron oscillator is a pivotal component in the landscape of electronic devices. Its ability to generate stable oscillations makes it a critical tool in communication systems and various other applications. By studying the transitron oscillator, we gain insight into the fundamental principles of electronics that continue to drive innovation and technological advancement. As we move forward, the lessons learned from this device will undoubtedly influence the next generation of electronic engineering.

电子世界充满了令人着迷的设备，这些设备彻底改变了我们沟通和处理信息的方式。其中一个这样的设备就是transitron oscillator，这是一项显著的发明，为信号生成领域做出了重要贡献。理解transitron oscillator需要深入探讨其组成、功能和应用。在其核心，transitron oscillator是一种电子振荡器，利用一种特殊的半导体设备——转导管（transitron）。该设备旨在以特定频率产生振荡，使其非常适合用于通信系统、无线电发射机，甚至某些类型的计算机中。transitron oscillator通过将直流电（DC）转换为交流电（AC）信号来工作，从而生成可用于传输数据的波形。transitron oscillator的操作基于反馈和共振的原理。当电源供应到转导管时，它进入一个可以在导电和非导电状态之间切换的状态。这种切换动作创建了一个反馈回路，以维持振荡。这些振荡的频率可以通过调整电路中的各种参数（如电阻和电容）来精细调节。这种可调性是transitron oscillator的关键优势之一，因为它允许工程师设计能够在多个频率范围内高效运行的电路。在实际应用中，transitron oscillator被证明是无价的。例如，在射频（RF）应用中，它用于生成可以远距离传输的信号。保持稳定频率的能力使其非常适合用于通信系统，其中清晰度和一致性至关重要。此外，transitron oscillator还出现在各种消费电子产品中，包括电视和收音机，在这些产品中，它帮助确保信号被准确处理。此外，transitron oscillator在更先进技术的发展中也发挥了作用。在数字计算领域，振荡器对于时序目的至关重要。它们帮助同步计算机内部的操作，确保数据及时处理。随着技术的不断进步，transitron oscillator背后的原理正在应用于需要精确控制频率和时序的新型更复杂的设备中。尽管有许多优点，transitron oscillator也面临挑战。例如，在高频应用中保持稳定性可能是困难的，工程师必须仔细设计电路以减轻噪声和信号失真等问题。此外，随着技术的发展，新的振荡器类型正在被开发，可能提供比传统transitron oscillator更好的性能或效率。然而，理解transitron oscillator所获得的基础知识仍然对任何希望探索电子领域的人来说是相关和必要的。总之，transitron oscillator是电子设备领域的一个关键组成部分。它生成稳定振荡的能力，使其成为通信系统和各种其他应用中的关键工具。通过研究transitron oscillator，我们获得了对继续推动创新和技术进步的电子学基本原理的深入了解。随着我们向前发展，从这一设备中获得的经验教训无疑将影响下一代电子工程。