circuitry
简明释义
n. 电路;电路系统;电路学;一环路
英英释义
单词用法
电子电路图;电子电路学 |
同义词
| 布线 | 这栋建筑的布线需要更新。 | ||
| 电气系统 | 这所房子的电气系统非常高效。 | ||
| 网络 | 他正在研究计算机科学中的电路网络。 | ||
| 电路 | 该电路设计用于处理高电压。 |
反义词
| 断开 | The disconnection of the circuitry caused the device to stop functioning. | 电路的断开导致设备停止工作。 | |
| 混乱 | In a state of chaos, the circuitry was unable to process any signals. | 在混乱状态下,电路无法处理任何信号。 |
例句
1.Instead, external circuitry is used to change its effective length.
而是通过外部电路来计算其有效长度。
2.The fact is that most of our senses have some interacting circuitry between them, which is called cross modality.
事实是,我们的大多数感觉之间拥有相互影响的线路,这被称为交叉模式。
3.Quite simply, a core is the circuitry that executes computer commands.
很简单,核心(core)就是执行计算机命令的电路部件。
4.One study found that rats fed foods like cheesecake and chocolate showed differences in brain circuitry after just 40 days.
一项研究发现,只需给老鼠喂食芝士蛋糕和巧克力40天,它们的大脑回路便会出现变化。
5.The company produced circuitry for communications systems.
这家公司为通讯系统生产电路系统。
6.And the brain chemical dopamine was elevated-dopamine is a crucial part of the brain's reward circuitry.
并且大脑的化学物质多巴胺也提升了——多巴胺是大脑反馈回路的重要组成部分。
7.Music isn't the only cultural experience that affects the brain's reward circuitry.
音乐并不是唯一影响脑部反馈回路的文化体验。
8.Neurological studies show that learning to read changes the brain's circuitry.
神经学研究显示,学习阅读的过程可以改变大脑的神经反应线路。
9.Some sensors have their own data smoothing internal circuitry.
某些传感器自身就具有数据平滑内部电路。
10.She studied the circuitry 电路 of the robot to improve its efficiency.
她研究了机器人的电路以提高其效率。
11.Modern devices often have intricate circuitry 电路 that requires specialized knowledge to repair.
现代设备通常具有复杂的电路,需要专业知识进行维修。
12.After examining the circuitry 电路, we found a short circuit that caused the failure.
检查完电路后,我们发现了导致故障的短路。
13.The complexity of the circuitry 电路 made it difficult to troubleshoot the problem.
由于电路的复杂性,排查问题变得困难。
14.The engineer explained how the circuitry 电路 in the device controlled its functions.
工程师解释了设备中如何通过电路控制其功能。
作文
In the modern world, technology plays a pivotal role in our daily lives. One of the fundamental components that enable various electronic devices to function efficiently is their circuitry. The term circuitry refers to the interconnected pathways that allow electrical signals to flow through electronic systems. This intricate web of connections forms the backbone of devices ranging from simple household appliances to complex computers and smartphones.Understanding circuitry is essential for anyone interested in electronics or engineering. It encompasses not just the physical wires and components, but also the design and layout that determine how effectively these elements work together. For instance, in a smartphone, the circuitry must be meticulously designed to ensure that all features, such as the camera, touchscreen, and battery management system, operate seamlessly. Any flaw in the circuitry could lead to malfunction or reduced performance, which is why engineers invest significant time in testing and optimizing these designs.Moreover, the evolution of circuitry has been remarkable over the past few decades. With advancements in technology, we have seen a shift from bulky, discrete components to integrated circuits (ICs) that pack millions of transistors into a single chip. This miniaturization allows for more powerful devices that are lighter and more energy-efficient. As a result, today’s smartphones possess capabilities that were unimaginable just a few years ago, all thanks to sophisticated circuitry.The importance of circuitry extends beyond consumer electronics. In the field of robotics, for example, the circuitry determines how robots perceive their environment and respond to stimuli. Sensors, motors, and microcontrollers work together within a robot's circuitry to enable it to perform tasks autonomously. This integration of hardware and software is a testament to the significance of circuitry in modern engineering and technology.In education, learning about circuitry can inspire the next generation of innovators. Many schools now offer programs that teach students the basics of electronics, allowing them to build simple circuits and understand how different components interact. These foundational skills are crucial for students who wish to pursue careers in STEM (science, technology, engineering, and mathematics) fields. By fostering an early interest in circuitry, educators can help cultivate a workforce capable of driving future technological advancements.In conclusion, circuitry is a vital aspect of modern technology that influences nearly every electronic device we use today. Its complexity and importance cannot be overstated, as it underpins the functionality and efficiency of countless systems. Whether in consumer electronics, robotics, or education, understanding circuitry opens up a world of possibilities for innovation and development. As technology continues to evolve, so too will the circuitry that powers our devices, making it an exciting field to watch and engage with in the coming years.
在现代世界中,技术在我们日常生活中扮演着至关重要的角色。使各种电子设备高效运行的基本组成部分之一是它们的电路。术语电路指的是允许电信号在电子系统中流动的互连路径。这张复杂的连接网络构成了从简单家用电器到复杂计算机和智能手机等设备的基础。理解电路对于任何对电子或工程感兴趣的人来说都是必不可少的。它不仅包括物理电线和组件,还包括决定这些元素如何有效协同工作的设计和布局。例如,在智能手机中,电路必须经过精心设计,以确保所有功能(如相机、触摸屏和电池管理系统)无缝运行。电路中的任何缺陷都可能导致故障或性能下降,这就是为什么工程师在测试和优化这些设计上投入大量时间。此外,过去几十年中电路的演变是显著的。随着技术的进步,我们已经看到从笨重的分立组件转向将数百万个晶体管打包到单个芯片中的集成电路(IC)。这种小型化使得更强大的设备变得更轻、更节能。因此,今天的智能手机拥有的功能在几年前是不可想象的,这一切都要归功于复杂的电路。电路的重要性超出了消费电子产品的范围。例如,在机器人领域,电路决定了机器人如何感知环境并对刺激作出反应。传感器、电机和微控制器在机器人的电路中协同工作,使其能够自主执行任务。这种硬件和软件的集成证明了电路在现代工程和技术中的重要性。在教育方面,学习电路可以激发下一代创新者。许多学校现在提供教授电子学基础的课程,让学生建立简单电路并理解不同组件如何相互作用。这些基础技能对于希望从事STEM(科学、技术、工程和数学)领域职业的学生至关重要。通过培养学生对电路的早期兴趣,教育工作者可以帮助培养能够推动未来技术进步的劳动力。总之,电路是现代技术的一个重要方面,影响着我们今天使用的几乎每一个电子设备。它的复杂性和重要性不可低估,因为它支撑着无数系统的功能和效率。无论是在消费电子、机器人还是教育中,理解电路为创新和发展打开了一个可能性的大门。随着技术的不断演进,推动我们设备的电路也将不断发展,使其成为一个令人兴奋的领域,值得在未来几年关注和参与。
