transistor
简明释义
英[trænˈzɪstə(r)]美[trænˈzɪstərˌtrænˈsɪstər]
n. 晶体管;晶体管收音机(transistor radio)
复 数 t r a n s i s t o r s
英英释义
单词用法
[计]场效应晶体管 | |
双极型晶体管 |
同义词
半导体 | The transistor is a key component in modern electronic devices. | 晶体管是现代电子设备中的关键组成部分。 |
反义词
电阻器 | 电阻器限制了电路中的电流。 | ||
绝缘体 | 绝缘体用于防止电流流动。 |
例句
1.On a basic bipolar transistor, with ports for electrical input and output, the law applies straightforwardly.
在一般的双极晶体管,带有电输入和输出端口,这定律完全适用。
2.Eg.tching time of the new-type transistor is shortened 3 times.
新型晶体管的开关时间缩短了1/3(即缩短到2/3)。
3.One idea for dealing with leaks is to change that by moving transistor design into three dimensions.
一个解决电流泄漏的想法是,将晶体管的设计变为三维结构。
4.Switching time of the new-type transistor is shortened 3 times.
新型晶体管的开关时间缩短了2/3(即缩短到1/3)。
5.A transistor needs to be completely semiconducting to hold information, Tour says.
图尔表示,晶体管必须是纯粹的半导体才能传载信息。
6.The equivalent of the bucket tipping is provided by a transistor which shorts out the capacitor when triggered.
晶体管提供了类似让吊桶倾倒的作用——每当被触发时它就使电容短路。
7.Every transistor has at least three electrodes.
每个晶体管至少有三个电极。
8.Yes, that's right. The transistor.
是的,没错就是晶体管。
9.The resistor and the capacitor together were the timer, and the transistor worked as the switch.
电阻器和电容器一起组成计时器,晶体管作为开关。
10.The radio uses a small transistor 晶体管 to amplify the sound.
这台收音机使用一个小的transistor 晶体管来放大声音。
11.Many modern computers rely on millions of transistors 晶体管 for processing data.
许多现代计算机依赖数百万个transistors 晶体管来处理数据。
12.A transistor 晶体管 can act as both a switch and an amplifier in electronic circuits.
在电子电路中,transistor 晶体管可以同时作为开关和放大器。
13.The invention of the transistor 晶体管 revolutionized the electronics industry.
transistor 晶体管的发明彻底改变了电子工业。
14.You can find a transistor 晶体管 in almost every electronic device today.
今天几乎每种电子设备中都可以找到transistor 晶体管。
作文
The invention of the transistor has revolutionized the world of electronics and communication. Before its creation, electronic devices relied heavily on vacuum tubes, which were bulky, inefficient, and consumed a lot of power. The transistor, a semiconductor device that can amplify or switch electronic signals, was developed in the late 1940s by John Bardeen, Walter Brattain, and William Shockley at Bell Labs. This innovation paved the way for modern technology as we know it today. One of the most significant advantages of the transistor is its size. Unlike vacuum tubes, which could be as large as a light bulb, transistors are incredibly small and can be manufactured in vast quantities. This miniaturization has allowed for the development of compact electronic devices such as smartphones, laptops, and tablets. The ability to integrate millions of transistors onto a single chip has led to the proliferation of microprocessors, which are the brains behind most modern computing systems. In addition to size, transistors are also more energy-efficient than their vacuum tube predecessors. They require significantly less power to operate, which is crucial in today's world where battery life is a major concern for portable devices. The efficiency of transistors has enabled the design of devices that can run for hours or even days on a single charge, making them more convenient for users. Furthermore, the reliability of transistors has contributed to their widespread adoption. Unlike vacuum tubes, which could burn out and required frequent replacements, transistors are solid-state devices that can last for many years without failure. This durability has made them the preferred choice for both consumer electronics and industrial applications. The impact of the transistor extends beyond just consumer electronics. In telecommunications, transistors play a crucial role in signal processing and amplification, enabling clearer and more reliable communication. They are also essential in various medical devices, automotive systems, and renewable energy technologies, highlighting their versatility and importance in numerous fields. As we look to the future, the transistor will continue to evolve. Researchers are exploring new materials and designs to create even smaller and more efficient transistors, which could lead to breakthroughs in quantum computing and other advanced technologies. The ongoing development of transistors demonstrates how a simple invention can have far-reaching implications, shaping the course of technology and society. In conclusion, the transistor is a fundamental building block of modern electronics. Its invention marked the beginning of a new era in technology, enabling the development of smaller, more efficient, and reliable devices. As we continue to innovate and push the boundaries of what is possible, the transistor will undoubtedly remain at the forefront of technological advancement, influencing our lives in ways we cannot yet imagine.
晶体管的发明彻底改变了电子和通信的世界。在其创造之前,电子设备主要依赖于真空管,这些真空管体积庞大、效率低下且耗电量大。晶体管是一种可以放大或切换电子信号的半导体器件,于20世纪40年代末由约翰·巴丁、沃尔特·布拉顿和威廉·肖克利在贝尔实验室开发。这一创新为我们今天所知的现代技术铺平了道路。 晶体管的一个重要优势是其体积。与可能像灯泡一样大的真空管不同,晶体管非常小,并且可以大量生产。这种微型化使得智能手机、笔记本电脑和平板电脑等紧凑型电子设备的发展成为可能。将数百万个晶体管集成到单个芯片上的能力导致了微处理器的普及,而微处理器是大多数现代计算系统的核心。 除了体积外,晶体管的能效也比其真空管前身高得多。它们在运行时所需的功率显著更少,这在当今电池寿命是便携设备主要关注点的世界中至关重要。晶体管的高效性使得设备能够在单次充电下运行数小时甚至数天,从而使用户更加方便。 此外,晶体管的可靠性也促进了它们的广泛应用。与可能会烧坏并需要频繁更换的真空管不同,晶体管是固态器件,可以在许多年内不发生故障。这种耐用性使它们在消费电子产品和工业应用中成为首选。 晶体管的影响不仅仅局限于消费电子。在电信领域,晶体管在信号处理和放大中起着至关重要的作用,使通信更加清晰和可靠。它们在各种医疗设备、汽车系统和可再生能源技术中也至关重要,突显了它们在多个领域的多功能性和重要性。 展望未来,晶体管将继续发展。研究人员正在探索新材料和设计,以创建更小、更高效的晶体管,这可能会导致量子计算和其他先进技术的突破。晶体管的持续发展证明了一个简单的发明可以产生深远的影响,塑造技术和社会的进程。 总之,晶体管是现代电子的基本构建块。它的发明标志着技术新时代的开始,使得更小、更高效和更可靠的设备的发展成为可能。随着我们不断创新并推动可能性的边界,晶体管无疑将继续处于技术进步的前沿,以我们尚未想象的方式影响我们的生活。
文章标题:transistor的意思是什么
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