Anderson bridge

简明释义

1. 安德森电桥; 2. 安德森电桥测自感量; 3. 安德逊电桥;

英英释义

例句

1.During the lab session, students learned to set up the Anderson bridge 安德森桥 for their experiments.

在实验课上，学生们学习如何搭建安德森桥 安德森桥进行实验。

2.The Anderson bridge 安德森桥 is particularly useful for measuring small resistances accurately.

对于精确测量小电阻，安德森桥 安德森桥特别有用。

3.The engineer explained how the Anderson bridge 安德森桥 works in a circuit.

工程师解释了安德森桥 安德森桥在电路中的工作原理。

4.In our physics class, we performed an experiment using the Anderson bridge 安德森桥 to determine the value of a capacitor.

在我们的物理课上，我们使用安德森桥 安德森桥进行实验以确定电容器的值。

5.We used the Anderson bridge 安德森桥 to measure the resistance of the unknown resistor.

我们使用安德森桥 安德森桥来测量未知电阻的电阻值。

作文

The Anderson bridge is a significant structure in the field of electrical engineering, particularly known for its application in measuring inductance. This bridge was developed by the engineer Robert Anderson in the late 19th century. It is designed to provide accurate measurements of inductors and is often used in laboratories and educational institutions to demonstrate the principles of electrical circuits. The Anderson bridge operates on the principle of balancing two legs of a bridge circuit, allowing for precise calculations of inductance by comparing it to known resistances and capacitances. In practical terms, the Anderson bridge consists of four arms: two resistive arms and two reactive arms, where one of the reactive arms contains the inductor whose value is to be measured. By adjusting the known resistances and using a galvanometer to detect the balance point, engineers can determine the unknown inductance with great accuracy. This method is particularly useful because it minimizes the errors that can occur due to variations in frequency and temperature, which can affect inductive measurements.Moreover, the Anderson bridge has paved the way for advancements in various fields, including telecommunications and circuit design. As technology has evolved, the principles behind the Anderson bridge have been integrated into more complex systems, yet the fundamental concept remains relevant. Understanding this bridge not only aids in grasping the basics of inductance but also enhances one's ability to engage with more advanced electrical engineering concepts.In educational settings, the Anderson bridge serves as an excellent teaching tool. Students can visually see the relationships between resistance, inductance, and capacitance, helping them to build a solid foundation in electrical theory. Experiments involving the Anderson bridge allow students to engage hands-on with the material, fostering a deeper understanding of how these components interact within a circuit.Furthermore, the historical significance of the Anderson bridge cannot be overlooked. It represents a pivotal moment in the development of measurement techniques in electrical engineering. Prior to its invention, measuring inductance was often imprecise and cumbersome. The introduction of the Anderson bridge revolutionized the field, making it more accessible and reliable for engineers and technicians alike.In conclusion, the Anderson bridge is not just a simple measuring device; it is a cornerstone of electrical engineering that continues to influence modern practices. Its ability to provide accurate inductance measurements has made it indispensable in both academic and professional environments. As technology progresses, the legacy of the Anderson bridge will undoubtedly endure, reminding us of the importance of innovation in the pursuit of knowledge and precision in the world of electrical engineering.

安德森桥（Anderson bridge）是电气工程领域的重要结构，特别以其在测量电感方面的应用而闻名。该桥由工程师罗伯特·安德森（Robert Anderson）在19世纪末开发。它旨在提供电感器的准确测量，通常用于实验室和教育机构，以展示电路原理。安德森桥的工作原理是平衡桥电路的两个支路，通过将未知电感与已知电阻和电容进行比较，从而允许精确计算电感。在实际应用中，安德森桥由四个臂组成：两个电阻臂和两个反应臂，其中一个反应臂包含要测量的电感器。通过调整已知电阻并使用电流计检测平衡点，工程师可以非常准确地确定未知电感。这种方法特别有用，因为它最小化了由于频率和温度变化而可能导致的误差，这些变化会影响电感测量。此外，安德森桥为各个领域的进步铺平了道路，包括电信和电路设计。随着技术的发展，安德森桥背后的原理已被整合到更复杂的系统中，但基本概念仍然相关。理解这个桥不仅有助于掌握电感的基础知识，还增强了人们参与更高级电气工程概念的能力。在教育环境中，安德森桥作为优秀的教学工具。学生可以直观地看到电阻、电感和电容之间的关系，帮助他们在电气理论中建立扎实的基础。涉及安德森桥的实验让学生能够动手实践，培养他们对这些组件在电路中相互作用的更深理解。此外，安德森桥的历史意义不容忽视。它代表了电气工程测量技术发展的重要时刻。在其发明之前，测量电感往往不够精确且繁琐。安德森桥的引入彻底改变了这一领域，使工程师和技术人员能够更加便捷和可靠地进行测量。总之，安德森桥不仅仅是一个简单的测量设备；它是电气工程的基石，继续影响现代实践。它提供准确的电感测量的能力使其在学术和专业环境中不可或缺。随着技术的进步，安德森桥的遗产无疑会延续，提醒我们在追求知识和电气工程领域精确性的过程中创新的重要性。