circuity

简明释义

英[səˈkjuːɪti]美[sɜːrˈkjʊəti]

n. 迂回；迂曲；间接性

复 数 c i r c u i t i e s

英英释义

单词用法

同义词

反义词

例句

1.Computers with Ics not only were faster but were in a sense much smarter. Crammed with more memory and logic circuity, they could take on far more difficult workloads.

有了集成电路计算机不但算得更快，而且从某种意义上说更聪明了。由于装的记忆和逻辑装置更多了，所以它们可以从事更难的工作。(不能译为“较”)。

2.Circuity is to be avoided, and it is the duty of a good judge to determine litigations, lest one lawsuit arise out of another.

缠讼应当予以避免，优秀的法官在判决时应当避免使一个诉讼引发另一个诉讼。

3.The system hardware circuity and software programming concept are presented in detail.

较详细地叙述了系统硬件电路构成和软件编制思路。

4.To these question, this article will give some theory analysis: 1 the wind - electricity net circuity of malfunction, including simplicity and complexity.

针对这些问题，本文从以下几个方面进行理论探讨：(1)风电系统中，针对简单故障和复杂故障分别建立风电网等值电路图。

5.Computers with Ics not only were faster but were in a sense much smarter. Crammed with more memory and logic circuity, they could take on far more difficult workloads.

有了集成电路计算机不但算得更快，而且从某种意义上说更聪明了。由于装的记忆和逻辑装置更多了，所以它们可以从事更难的工作。(不能译为“较”)。

6.The circuity of the roads made the journey longer than expected.

道路的曲折性使旅程比预期的要长。

7.She admired the circuity of the plot in the novel, which kept her guessing until the end.

她欣赏小说情节的曲折性，一直让她猜测到最后。

8.The engineer explained the concept of circuity to illustrate how electricity flows in a complex system.

工程师解释了电路性的概念，以说明电流如何在复杂系统中流动。

9.The circuity involved in the legal process can often confuse those unfamiliar with the law.

法律程序中的电路性常常让不熟悉法律的人感到困惑。

10.Understanding the circuity of the network is crucial for troubleshooting connectivity issues.

理解网络的电路性对于排除连接问题至关重要。

作文

In the realm of electrical engineering, the term circuity refers to the complexity and configuration of electrical circuits. Understanding circuity is essential for engineers who design and analyze various systems, from simple household appliances to sophisticated computer networks. The concept of circuity encompasses not only the physical layout of wires and components but also the flow of electricity and how it interacts with different materials. One of the primary challenges in dealing with circuity is ensuring that the circuit functions efficiently. Engineers must consider factors such as resistance, capacitance, and inductance when designing a circuit. Resistance can cause energy loss in the form of heat, while capacitance and inductance can affect the timing and behavior of signals within the circuit. By understanding these properties, engineers can optimize the circuity to achieve the desired performance.Moreover, the circuity of a system can greatly influence its reliability. A circuit with too many components or complex pathways may be more prone to failure than a simpler design. This is particularly important in critical applications such as aerospace or medical devices, where circuit failures can have dire consequences. Therefore, engineers strive to create designs that minimize unnecessary circuity, thereby enhancing the overall robustness of the system.In addition to practical applications, the study of circuity also has theoretical implications. Researchers explore the mathematical models that describe how electrical current flows through different configurations. These models can help predict the behavior of circuits under various conditions, such as changes in temperature or load. By advancing our understanding of circuity, researchers can contribute to the development of new technologies and improve existing ones.Furthermore, the principles of circuity are not limited to electrical engineering; they can also be applied to other fields. For instance, in biology, the concept of circuity can be seen in neural networks, where the connections between neurons create complex pathways for information processing. Similarly, in computer science, algorithms can be designed to navigate through complex data structures, reflecting the same underlying principles of circuity found in electrical circuits.In conclusion, circuity is a multifaceted concept that plays a crucial role in various fields, particularly in electrical engineering. By grasping the intricacies of circuity, engineers can design more efficient, reliable, and innovative systems. As technology continues to evolve, the importance of understanding circuity will only grow, paving the way for advancements that can transform our daily lives. Whether in the context of electrical circuits, biological systems, or computational algorithms, the principles of circuity remain a vital area of study, highlighting the interconnectedness of different disciplines and the universal nature of complex systems.

在电气工程领域，术语circuity指的是电路的复杂性和配置。理解circuity对设计和分析各种系统的工程师至关重要，从简单的家用电器到复杂的计算机网络。circuity的概念不仅包含电线和组件的物理布局，还包括电流的流动及其与不同材料的相互作用。处理circuity时，主要挑战之一是确保电路高效运行。工程师在设计电路时必须考虑电阻、电容和电感等因素。电阻会导致能量以热量的形式损耗，而电容和电感则可能影响电路中信号的时序和行为。通过理解这些属性，工程师可以优化circuity以实现所需的性能。此外，系统的circuity会极大影响其可靠性。组件过多或路径复杂的电路可能比简单设计更容易出现故障。这在航空航天或医疗设备等关键应用中特别重要，因为电路故障可能带来严重后果。因此，工程师努力创建设计，以最小化不必要的circuity，从而增强系统的整体稳健性。除了实际应用，circuity的研究也具有理论意义。研究人员探索描述电流如何通过不同配置流动的数学模型。这些模型可以帮助预测电路在不同条件下的行为，例如温度或负载的变化。通过加深对circuity的理解，研究人员可以为新技术的发展做出贡献，并改善现有技术。此外，circuity的原理不仅限于电气工程，它们还可以应用于其他领域。例如，在生物学中，circuity的概念可以在神经网络中看到，其中神经元之间的连接创建了复杂的信息处理路径。同样，在计算机科学中，可以设计算法以遍历复杂的数据结构，反映出电路中发现的相同基本circuity原理。总之，circuity是一个多方面的概念，在各个领域，尤其是在电气工程中发挥着至关重要的作用。通过掌握circuity的复杂性，工程师可以设计出更高效、更可靠和更具创新性的系统。随着技术的不断发展，理解circuity的重要性只会增加，为能够改变我们日常生活的进步铺平道路。无论是在电路、电生物系统还是计算算法的背景下，circuity的原则仍然是一个重要的研究领域，突显了不同学科之间的相互联系以及复杂系统的普遍性。