electromagnetic coupling
简明释义
电磁耦合
英英释义
例句
1.Engineers must consider electromagnetic coupling (电磁耦合) when designing circuits to minimize interference.
工程师在设计电路时必须考虑电磁耦合以最小化干扰。
2.In MRI machines, electromagnetic coupling (电磁耦合) is used to generate images of the body's internal structures.
在MRI机器中,电磁耦合用于生成身体内部结构的图像。
3.The efficiency of transformers is largely determined by the quality of electromagnetic coupling (电磁耦合) between the coils.
变压器的效率在很大程度上取决于线圈之间的电磁耦合质量。
4.The design of wireless chargers relies heavily on electromagnetic coupling (电磁耦合) to transfer energy efficiently.
无线充电器的设计在很大程度上依赖于电磁耦合来高效地传输能量。
5.Wireless power transfer systems utilize electromagnetic coupling (电磁耦合) to deliver power without physical connections.
无线电力传输系统利用电磁耦合在没有物理连接的情况下传递电力。
作文
Electromagnetic coupling is a fundamental concept in the field of physics and engineering, particularly in the study of electromagnetic fields and their interactions with various materials. This phenomenon occurs when two or more circuits or systems influence each other through their electromagnetic fields. In simpler terms, electromagnetic coupling (电磁耦合) describes how energy can be transferred between different components without direct physical contact, relying instead on the principles of electromagnetism.One common example of electromagnetic coupling (电磁耦合) can be observed in transformers, which are widely used in electrical power distribution. Transformers operate on the principle of magnetic induction, where an alternating current in one coil generates a magnetic field that induces a voltage in a nearby coil. This interaction showcases how electromagnetic coupling (电磁耦合) allows for efficient energy transfer from one circuit to another, enabling the transformation of voltage levels in electrical systems.In addition to transformers, electromagnetic coupling (电磁耦合) is also crucial in wireless communication technologies. For instance, in devices such as smartphones and tablets, antennas utilize this principle to transmit and receive signals over the air. The design of these antennas often relies on optimizing the electromagnetic coupling (电磁耦合) between the transmitting and receiving elements, ensuring minimal loss of signal strength and maximum efficiency in communication.Moreover, electromagnetic coupling (电磁耦合) plays a significant role in modern medical technology, particularly in magnetic resonance imaging (MRI). MRI machines use powerful magnets and radio waves to generate detailed images of the inside of the human body. The electromagnetic coupling (电磁耦合) between the magnetic fields and the hydrogen atoms in the body allows for the visualization of soft tissues, providing critical information for medical diagnosis and treatment.Understanding electromagnetic coupling (电磁耦合) is not only essential for engineers and scientists but also for anyone interested in the technological advancements shaping our world today. As we continue to develop new technologies, the principles of electromagnetic coupling (电磁耦合) will remain at the forefront of innovation, influencing everything from renewable energy systems to advanced telecommunications.In conclusion, electromagnetic coupling (电磁耦合) is a vital concept that underpins many aspects of modern technology. Its ability to facilitate energy transfer and communication without direct contact opens up numerous possibilities for future advancements. By further exploring and understanding this phenomenon, we can continue to harness its potential to improve our lives and drive technological progress.
电磁耦合是物理学和工程学领域的一个基本概念,特别是在电磁场及其与各种材料相互作用的研究中。这一现象发生在两个或多个电路或系统通过其电磁场相互影响时。简单来说,electromagnetic coupling(电磁耦合)描述了能量如何在不同组件之间转移,而无需直接的物理接触,而是依赖于电磁学的原理。一个常见的例子是变压器,它们广泛用于电力分配。变压器的工作原理是磁感应,其中一个线圈中的交流电产生一个磁场,从而在附近的另一个线圈中感应出电压。这种相互作用展示了
相关单词
