astatic coil

简明释义

无定向线圈

英英释义

例句

1.To achieve better performance, the scientist replaced the standard coil with an astatic coil in the experiment.

为了获得更好的性能，科学家在实验中用无静态线圈替换了标准线圈。

2.The radio engineer designed an efficient receiver using an astatic coil to minimize interference.

这位无线电工程师设计了一种高效的接收器，使用了一个无静态线圈以最小化干扰。

3.An astatic coil is crucial in balancing the magnetic fields in sensitive measurement instruments.

在敏感测量仪器中，无静态线圈对于平衡磁场至关重要。

4.In audio applications, an astatic coil helps reduce noise and improve sound quality.

在音频应用中，无静态线圈有助于减少噪音并改善音质。

5.When constructing a telegraph system, the use of an astatic coil can enhance signal clarity.

在构建电报系统时，使用无静态线圈可以增强信号清晰度。

作文

In the realm of electrical engineering and physics, various components play pivotal roles in the functionality of circuits and devices. One such component is the astatic coil, which is crucial for minimizing the effects of external magnetic fields on sensitive instruments. Understanding the significance and operation of an astatic coil can enhance one’s grasp of electromagnetic principles and their applications in technology. An astatic coil is typically used in conjunction with a galvanometer or other measuring instruments. Its primary function is to counteract the influence of stray magnetic fields that can distort readings. The design of an astatic coil consists of two coils wound in opposite directions, which creates a balanced system. When an external magnetic field is present, the induced currents in the coils oppose each other, effectively canceling out the unwanted effects. This unique configuration allows for more accurate measurements, making it invaluable in laboratory settings and precise instrumentation.The importance of the astatic coil extends beyond just improving measurement accuracy. In environments where electromagnetic interference is prevalent, such as in industrial settings or near high-power transmission lines, the ability to shield sensitive equipment from these disturbances is critical. By employing an astatic coil, engineers can ensure that devices remain reliable and functional, thereby enhancing safety and efficiency in operations.Moreover, the concept of the astatic coil also serves as an excellent example of the principles of superposition and cancellation in physics. When studying electromagnetic fields, students often encounter scenarios where multiple fields interact. The astatic coil provides a practical illustration of how opposing forces can be utilized to achieve a desired outcome. This principle is not only applicable in electrical engineering but also finds relevance in various fields such as telecommunications, audio engineering, and even medical devices.As technology continues to advance, the role of components like the astatic coil becomes increasingly significant. With the rise of wireless communication and the proliferation of electronic devices, understanding how to mitigate the effects of electromagnetic interference is more important than ever. Engineers and scientists are continually exploring new materials and designs to enhance the performance of astatic coils and similar components, ensuring that they meet the demands of modern technology.In conclusion, the astatic coil is a vital component in the toolkit of electrical engineers and physicists. Its ability to reduce the impact of external magnetic fields on sensitive measurements demonstrates the elegance and practicality of electromagnetic theory. As we delve deeper into the complexities of our technological world, the astatic coil stands as a testament to the importance of foundational principles in achieving innovation and reliability in electronic systems.

在电气工程和物理学的领域中，各种组件在电路和设备的功能中发挥着关键作用。其中一个组件是无静态线圈，它对于最小化外部磁场对敏感仪器的影响至关重要。理解无静态线圈的重要性和操作可以增强人们对电磁原理及其在技术中应用的掌握。无静态线圈通常与电流计或其他测量仪器一起使用。它的主要功能是抵消能够扭曲读数的杂散磁场的影响。无静态线圈的设计由两个相反方向缠绕的线圈组成，这创建了一个平衡系统。当存在外部磁场时，在线圈中感应的电流相互抵消，有效地取消了不必要的影响。这种独特的配置允许更准确的测量，使其在实验室环境和精密仪器中不可或缺。无静态线圈的重要性不仅仅在于提高测量的准确性。在电磁干扰普遍存在的环境中，例如工业环境或靠近高功率输电线路的地方，保护敏感设备免受这些干扰的能力至关重要。通过采用无静态线圈，工程师可以确保设备保持可靠和功能，从而提高操作的安全性和效率。此外，无静态线圈的概念也是物理学中叠加和取消原理的一个极好例子。在学习电磁场时，学生们经常遇到多个场相互作用的情况。无静态线圈提供了一个实际的例子，说明如何利用相反的力来实现期望的结果。这个原理不仅适用于电气工程，还在电信、音频工程甚至医疗设备等各个领域具有相关性。随着技术的不断进步，像无静态线圈这样的组件的角色变得越来越重要。随着无线通信的兴起和电子设备的激增，理解如何减轻电磁干扰的影响比以往任何时候都更加重要。工程师和科学家们不断探索新的材料和设计，以提高无静态线圈及类似组件的性能，确保它们满足现代技术的要求。总之，无静态线圈是电气工程师和物理学家工具箱中的一个重要组件。它减少外部磁场对敏感测量影响的能力展示了电磁理论的优雅和实用性。随着我们深入探讨技术世界的复杂性，无静态线圈作为基础原理在实现电子系统创新和可靠性中的重要性的见证。