circuital

简明释义

[ˈsɜː.kɪ.təl][ˈsɜr.kɪ.tl]

adj. 与电路有关的

英英释义

Relating to or resembling a circuit, especially in the context of electrical circuits.

与电路相关或类似,尤其是在电气电路的上下文中。

Describing a path that is circular or goes around something.

描述一种环形或绕某物而行的路径。

单词用法

circuital current

电路电流

circuital path

电路路径

circuital analysis

电路分析

circuital resistance

电路电阻

同义词

circular

圆形的

The circuital route took us longer than expected.

这个环形路线比我们预期的要花更长时间。

looped

环形的

The circular design of the park allows for easy navigation.

公园的圆形设计便于导航。

roundabout

迂回的

He followed a looped path during his morning run.

他在晨跑时沿着环形小路跑。

反义词

linear

线性的

The path is linear, allowing for a direct route from point A to point B.

这条路径是线性的,允许从A点直接到达B点。

straight

直的

He prefers a straight approach to problem-solving rather than a circuital one.

他更喜欢直截了当的问题解决方法,而不是迂回的方式。

例句

1.This paper analyses the reason for the wrong solution and elaborates the founding condition of the ampere's circuital theorem.

本文分析了这种常见解答错误的原因。进而阐述了安培环路定理的成立条件。

2.This paper analyses the reason for the wrong solution and elaborates the founding condition of the ampere's circuital theorem.

本文分析了这种常见解答错误的原因。进而阐述了安培环路定理的成立条件。

3.The engineer designed a circuital 电路的 layout for the new electrical system.

工程师为新的电气系统设计了一个电路的布局。

4.The circuital 电路的 components were tested for durability and performance.

电路的组件进行了耐用性和性能测试。

5.In physics, we often study circuital 电路的 paths to understand electromagnetic fields.

在物理学中,我们经常研究电路的路径以理解电磁场。

6.He used a circuital 电路的 approach to solve the complex problem in electronics.

他采用了电路的方法来解决电子学中的复杂问题。

7.The circuital 电路的 analysis revealed several inefficiencies in the current design.

电路的分析揭示了当前设计中的几个低效之处。

作文

In the realm of physics and engineering, the term circuital refers to anything related to an electric circuit. Understanding this concept is crucial for anyone studying electronics or electrical engineering. A circuit is essentially a closed loop that allows electric current to flow, and the properties associated with this flow are described as circuital characteristics. For instance, when analyzing the behavior of electric currents, we often refer to circuital laws which govern how voltage, current, and resistance interact within a circuit. One of the most fundamental principles in understanding circuital behavior is Ohm's Law, which states that the current through a conductor between two points is directly proportional to the voltage across the two points and inversely proportional to the resistance of the conductor. This law is integral to designing circuits, as it helps engineers predict how much current will flow based on the applied voltage and the resistance present in the circuit. Moreover, the concept of circuital paths is essential when discussing complex circuits. In a simple series circuit, the current flows through a single path, while in parallel circuits, there are multiple paths for the current to take. Understanding these circuital configurations allows engineers to design systems that can handle different loads and perform efficiently under various conditions. In practical applications, the circuital analysis is not just limited to theoretical calculations; it also involves real-world testing and troubleshooting. Engineers often use tools such as multimeters and oscilloscopes to measure voltage, current, and resistance in actual circuits, ensuring that they operate within the desired parameters. These measurements help in verifying that the circuital designs function as intended before they are deployed in larger systems. Furthermore, the importance of circuital concepts extends beyond traditional electronics into emerging technologies like renewable energy systems. For example, in solar panel installations, understanding the circuital arrangement of photovoltaic cells is vital for maximizing energy output and efficiency. As the world increasingly shifts towards sustainable energy solutions, knowledge of circuital principles becomes even more relevant. In conclusion, the term circuital encompasses a wide range of concepts and applications in the field of electronics and engineering. From basic laws like Ohm's Law to complex circuit configurations, understanding circuital principles is fundamental for anyone looking to excel in these areas. As technology continues to advance, the relevance of circuital knowledge will only grow, making it an essential component of modern engineering education. In summary, the significance of circuital aspects in both theoretical and practical applications cannot be overstated. Whether one is designing a simple circuit or working on cutting-edge renewable energy systems, a solid grasp of circuital principles is critical for success in the field.

在物理和工程领域,术语circuital指的是与电路相关的任何事物。理解这个概念对于任何学习电子学或电气工程的人来说都是至关重要的。电路本质上是一个闭合回路,允许电流流动,与此流动相关的特性被描述为circuital特性。例如,在分析电流行为时,我们常常提到控制电压、电流和电阻在电路中相互作用的circuital定律。理解circuital行为的一个基本原则是欧姆定律,该定律指出,导体之间的电流与两点之间的电压成正比,与导体的电阻成反比。这个定律对于电路设计至关重要,因为它帮助工程师预测在施加电压和电路中存在的电阻下将会有多少电流流动。此外,当讨论复杂电路时,circuital路径的概念也是必不可少的。在简单的串联电路中,电流通过单一路径流动,而在并联电路中,电流可以通过多个路径流动。理解这些circuital配置使工程师能够设计能够处理不同负载并在各种条件下高效运行的系统。在实际应用中,circuital分析不仅限于理论计算;它还涉及现实世界的测试和故障排除。工程师通常使用万用表和示波器等工具来测量实际电路中的电压、电流和电阻,确保它们在所需参数范围内运行。这些测量有助于验证circuital设计在投入更大系统之前是否按预期工作。此外,circuital概念的重要性超越了传统电子学,延伸到了可再生能源系统等新兴技术。例如,在太阳能电池板安装中,理解光伏电池的circuital排列对于最大化能量输出和效率至关重要。随着世界日益向可持续能源解决方案转变,掌握circuital原理变得更加相关。总之,术语circuital涵盖了电子和工程领域的一系列概念和应用。从基本的欧姆定律到复杂的电路配置,理解circuital原理对于任何希望在这些领域中取得成功的人来说都是基础。随着技术的不断进步,circuital知识的相关性只会增加,使其成为现代工程教育的重要组成部分。总之,circuital方面在理论和实际应用中的重要性不容小觑。无论是设计简单电路还是从事尖端可再生能源系统的工作,对circuital原理的扎实掌握都是在该领域取得成功的关键。