faradism

简明释义

英[ˈfærədɪzəm]美[ˈfærəˌdɪzəm]

n. 感应电；感应电学

英英释义

单词用法

同义词

反义词

例句

1.ObjectiveTo explore the effect of neuromuscular facilitation combined with faradism on limbs motor function in hemiplegic patient with early stroke.

目的研究脑卒中偏瘫早期神经促进技术和感应电治疗对肢体运动功能恢复的效果。

2.ObjectiveTo explore the effect of neuromuscular facilitation combined with faradism on limbs motor function in hemiplegic patient with early stroke.

目的研究脑卒中偏瘫早期神经促进技术和感应电治疗对肢体运动功能恢复的效果。

3.The postural control training combined faradism can significantly improve the activities of daily living function in stroke patients.

姿势控制训练对脑卒中患者日常生活能力改善有促进作用。

4.The principles of faradism are often applied in modern electrical engineering.

现代电气工程中经常应用法拉第主义的原理。

5.Understanding faradism can help students grasp the fundamentals of electromagnetism.

理解法拉第主义可以帮助学生掌握电磁学的基础。

6.In physics classes, we learned how faradism relates to electric fields.

在物理课上，我们学习了法拉第主义与电场的关系。

7.The concept of faradism is crucial for understanding capacitors.

法拉第主义的概念对于理解电容器至关重要。

8.Many inventions in the field of electricity are based on the theories of faradism.

许多电力领域的发明都基于法拉第主义的理论。

作文

In the realm of physics and electrical engineering, various concepts and principles have shaped our understanding of electricity and magnetism. One such concept is faradism, which refers to the study and application of capacitance, particularly in relation to the behavior of capacitors in electric circuits. The term is derived from the name of the renowned scientist Michael Faraday, who made significant contributions to the field of electromagnetism. Understanding faradism is crucial for anyone interested in electronics or electrical engineering, as it lays the groundwork for many practical applications. Capacitance is a fundamental property of electrical components that allows them to store and release electrical energy. This property is measured in farads, named after Faraday. A capacitor, which is a device that stores electrical energy, is characterized by its capacitance value. The larger the capacitance, the more charge the capacitor can store. This principle is essential in various applications, including power supply systems, signal processing, and energy storage devices. The importance of faradism extends beyond theoretical knowledge; it has practical implications in everyday technology. For instance, capacitors are widely used in electronic devices such as smartphones, computers, and televisions. They help smooth out voltage fluctuations, filter signals, and provide temporary power during brief interruptions in supply. Without a solid understanding of faradism, engineers would struggle to design efficient and reliable electronic systems. Moreover, the study of faradism involves understanding the relationship between voltage, current, and time in capacitive circuits. When a capacitor is charged, it stores energy in the form of an electric field, and when it is discharged, this energy is released back into the circuit. The rate at which a capacitor charges and discharges is influenced by the resistance in the circuit, leading to important concepts such as time constant and RC (resistor-capacitor) circuits. In addition to its applications in electronics, faradism also plays a role in various scientific fields, including chemistry and biology. For example, capacitive sensing technology is utilized in touchscreens and other interactive devices, allowing for intuitive user interfaces. Understanding the principles behind faradism enables researchers and developers to innovate and improve technology continuously. Furthermore, as we move towards a more sustainable future, the study of faradism is becoming increasingly relevant. Capacitors are essential components in renewable energy systems, such as solar panels and wind turbines, where they help manage energy storage and distribution. By harnessing the principles of faradism, we can develop more efficient energy systems that contribute to reducing our carbon footprint. In conclusion, faradism encompasses a vital area of study within the fields of physics and electrical engineering. Its principles are foundational to understanding how capacitors function and their applications in modern technology. As we continue to advance in our technological capabilities, the significance of faradism will only grow, highlighting the importance of this concept in both theoretical and practical contexts. Embracing the knowledge of faradism equips us with the tools necessary to innovate and tackle the challenges of the future, making it an essential topic for students and professionals alike.

在物理和电气工程领域，各种概念和原理塑造了我们对电和磁的理解。其中一个概念是法拉第主义，它指的是电容的研究和应用，特别是与电路中电容器的行为有关。这个术语源于著名科学家迈克尔·法拉第的名字，他对电磁学领域做出了重大贡献。理解法拉第主义对于任何对电子或电气工程感兴趣的人来说都是至关重要的，因为它为许多实际应用奠定了基础。 电容是电气元件的基本属性，允许它们存储和释放电能。这个属性以法拉（farad）为单位进行测量，法拉是以法拉第的名字命名的。电容器是一种存储电能的设备，其特征是其电容值。电容越大，电容器可以存储的电荷就越多。这一原理在各种应用中都是必不可少的，包括电源系统、信号处理和能量存储设备。 法拉第主义的重要性超越了理论知识；它在日常技术中具有实际意义。例如，电容器广泛用于智能手机、计算机和电视等电子设备中。它们有助于平滑电压波动、过滤信号，并在供电短暂中断时提供临时电力。如果没有对法拉第主义的透彻理解，工程师将难以设计高效可靠的电子系统。 此外，法拉第主义的研究涉及理解电容电路中电压、电流和时间之间的关系。当电容器被充电时，它以电场的形式存储能量，而当它放电时，这种能量又释放回电路。电容器充电和放电的速率受到电路中电阻的影响，导致时间常数和RC（电阻-电容）电路等重要概念。 除了在电子学中的应用外，法拉第主义还在化学和生物学等多个科学领域发挥着作用。例如，电容传感技术被广泛应用于触摸屏和其他交互式设备，使得用户界面更加直观。理解法拉第主义背后的原理使研究人员和开发者能够不断创新和改善技术。 此外，随着我们朝着更可持续的未来发展，法拉第主义的研究变得越来越相关。电容器是可再生能源系统中的重要组成部分，如太阳能电池板和风力涡轮机，在这些系统中，它们有助于管理能量存储和分配。通过利用法拉第主义的原理，我们可以开发出更高效的能源系统，从而有助于减少我们的碳足迹。 总之，法拉第主义涵盖了物理和电气工程领域内的重要研究领域。它的原理是理解电容器如何工作及其在现代技术中的应用的基础。随着我们在技术能力上的不断进步，法拉第主义的重要性只会增加，突显出这一概念在理论和实际背景下的重要性。掌握法拉第主义的知识为我们提供了必要的工具，以创新并应对未来的挑战，使其成为学生和专业人士都必须关注的主题。