magnetic delay-line

简明释义

磁延迟线

英英释义

例句

1.By incorporating a magnetic delay-line, the audio equipment achieved better sound quality.

通过加入磁延迟线，音频设备实现了更好的音质。

2.The design of the radar system included a magnetic delay-line to enhance target detection.

雷达系统的设计包括一个磁延迟线以增强目标检测能力。

3.The magnetic delay-line is crucial for ensuring data integrity in high-speed computing applications.

在高速计算应用中，磁延迟线对于确保数据完整性至关重要。

4.In the laboratory, researchers used a magnetic delay-line to study the effects of magnetic fields on wave propagation.

在实验室中，研究人员使用磁延迟线研究磁场对波传播的影响。

5.The engineers decided to implement a magnetic delay-line to improve signal processing in the communication system.

工程师们决定实施一个磁延迟线来改善通信系统中的信号处理。

作文

The concept of a magnetic delay-line is pivotal in the field of electronics and signal processing. Essentially, a magnetic delay-line is a device that uses magnetic fields to delay the transmission of signals. This technology was particularly significant during the mid-20th century when advancements in telecommunications were rapidly evolving. By utilizing the properties of magnetic materials, engineers were able to create systems that could effectively manage the timing of signals in various applications.In a typical magnetic delay-line, a signal is transmitted through a medium that possesses magnetic characteristics. This medium can be made from various materials, including ferrites or other magnetic substances. The delay is achieved by the interaction of the signal with the magnetic field within the medium. As the signal propagates through this medium, its speed is altered, resulting in a delayed output compared to the input. This property is beneficial for synchronizing signals in complex electronic systems.One of the most notable applications of magnetic delay-lines has been in radar technology. In radar systems, precise timing is crucial for accurately determining the distance and speed of objects. By employing magnetic delay-lines, engineers were able to enhance the performance of radar systems, allowing for better detection capabilities and improved accuracy. Additionally, magnetic delay-lines have been utilized in various communication devices, such as telephones and television sets, where timing and synchronization play a critical role in delivering clear and coherent signals.As technology has advanced, the use of magnetic delay-lines has evolved. While they were once a staple in older electronic systems, modern technologies have introduced alternative methods for achieving similar delays, such as digital signal processing techniques. However, understanding the principles behind magnetic delay-lines remains essential for anyone studying electronics or signal processing. The fundamental concepts of magnetism and wave propagation are crucial for grasping how these devices function and their historical significance in technological development.Moreover, the study of magnetic delay-lines opens up discussions about the future of signal processing. As we continue to push the boundaries of technology, the need for efficient and effective signal management will only grow. Researchers are exploring new materials and methods to improve the functionality of magnetic delay-lines, potentially leading to innovations that could redefine how we approach signal transmission in the future.In conclusion, the magnetic delay-line serves as a foundational element in the realm of electronics and telecommunications. Its ability to manipulate signal timing through magnetic interactions has paved the way for advancements in various technologies. While newer methods may have emerged, the importance of understanding magnetic delay-lines cannot be overstated. They represent a significant step in our journey toward mastering signal processing, and their legacy continues to influence modern electronic design and application. As we look to the future, the principles derived from magnetic delay-lines will undoubtedly play a role in shaping the next generation of technological innovations.

“磁延迟线”这一概念在电子学和信号处理领域中至关重要。基本上，magnetic delay-line 是一种利用磁场来延迟信号传输的设备。这项技术在20世纪中期尤其重要，当时电信技术迅速发展。通过利用磁性材料的特性，工程师能够创建可以有效管理各种应用中信号时序的系统。在典型的magnetic delay-line中，信号通过具有磁性特性的介质传输。该介质可以由各种材料制成，包括铁氧体或其他磁性物质。延迟是通过信号与介质中的磁场相互作用来实现的。当信号在该介质中传播时，其速度会被改变，从而导致输出信号与输入信号相比出现延迟。这一特性对于在复杂电子系统中同步信号非常有益。magnetic delay-lines最显著的应用之一是在雷达技术中。在雷达系统中，精确的时序对于准确确定物体的距离和速度至关重要。通过采用magnetic delay-lines，工程师能够增强雷达系统的性能，提高探测能力和准确度。此外，magnetic delay-lines还被用于各种通信设备中，如电话和电视机，在这些设备中，时序和同步对于提供清晰一致的信号起着关键作用。随着技术的进步，magnetic delay-lines的使用也在不断演变。虽然它们曾经是旧电子系统中的重要组成部分，但现代技术引入了替代方法来实现类似的延迟，例如数字信号处理技术。然而，理解magnetic delay-lines背后的原理对于任何学习电子学或信号处理的人来说仍然至关重要。磁性和波传播的基本概念对理解这些设备的功能及其在技术发展中的历史重要性至关重要。此外，对magnetic delay-lines的研究引发了关于信号处理未来的讨论。随着我们不断推动技术的边界，对高效有效的信号管理的需求只会增长。研究人员正在探索新材料和方法，以改善magnetic delay-lines的功能，可能会导致重新定义我们未来信号传输方法的创新。总之，magnetic delay-line作为电子学和电信领域的基础元素，其通过磁相互作用操纵信号时序的能力为各种技术的进步铺平了道路。尽管可能出现了更新的方法，但理解magnetic delay-lines的重要性不容低估。它们代表了我们在掌握信号处理过程中迈出的重要一步，并且它们的遗产继续影响现代电子设计和应用。展望未来，从magnetic delay-lines中获得的原理无疑将在塑造下一代技术创新中发挥作用。