transistor driven

简明释义

晶体管激励的

英英释义

例句

1.Many modern televisions are transistor driven, making them more efficient and compact.

许多现代电视都是晶体管驱动的，使它们更加高效和紧凑。

2.In the latest smartphone, the camera module is transistor driven for faster processing.

在最新的智能手机中，相机模块是晶体管驱动的，以实现更快的处理速度。

3.The robotics project uses a transistor driven motor controller to enhance performance.

这个机器人项目使用晶体管驱动的电机控制器来提高性能。

4.Our research focuses on transistor driven circuits for renewable energy applications.

我们的研究专注于可再生能源应用中的晶体管驱动的电路。

5.The new audio amplifier is a transistor driven system, which allows for better sound quality.

这个新的音频放大器是一个晶体管驱动的系统，能够提供更好的音质。

作文

In the world of electronics, the term transistor driven refers to devices and circuits that utilize transistors as their primary components for amplification and switching. Transistors are fundamental building blocks in modern electronic devices, allowing for the control of electrical signals with great precision. They have replaced vacuum tubes in most applications due to their smaller size, greater reliability, and lower power consumption. The significance of transistor driven technology can be seen in various aspects of our daily lives, particularly in communication, computing, and entertainment. To understand the impact of transistor driven technology, we need to look at its historical context. The invention of the transistor in 1947 by John Bardeen, Walter Brattain, and William Shockley marked a revolutionary change in electronics. Before transistors, vacuum tubes were used in radios, televisions, and early computers, but they were bulky, fragile, and consumed a lot of power. The introduction of transistors allowed for smaller, more efficient devices that could perform better and last longer. This shift paved the way for the development of integrated circuits, which further miniaturized electronic components and led to the creation of modern computers and smartphones. One of the most significant advantages of transistor driven devices is their ability to amplify electrical signals. In audio equipment, for instance, transistors are used to boost sound signals, enabling high-quality music playback. Similarly, in radio transmitters, transistors help modulate and amplify signals for clearer transmission over long distances. This capability has transformed the way we communicate, making it possible to have portable devices that connect us globally. Moreover, the use of transistor driven technology extends beyond audio and communication. In computing, transistors serve as the fundamental units of processing power. Modern processors contain billions of transistors, all working together to perform complex calculations and execute programs. The speed and efficiency of computers have drastically improved thanks to advancements in transistor technology, enabling us to perform tasks that were once unimaginable. From simple calculations to advanced artificial intelligence, the role of transistors cannot be overstated. In addition to their performance benefits, transistor driven devices are also more energy-efficient compared to their predecessors. As concerns about energy consumption and environmental impact grow, the demand for low-power electronics increases. Transistors consume significantly less power than vacuum tubes, leading to longer battery life in portable devices and reduced energy costs for consumers. This efficiency is crucial in a world where sustainable practices are becoming a priority. Furthermore, the versatility of transistor driven technology allows for innovation across various fields. In medical devices, for example, transistors are used in diagnostic equipment, monitoring systems, and even in life-saving devices such as pacemakers. The ability to miniaturize these devices while maintaining functionality is vital for patient care and treatment. In conclusion, the term transistor driven encapsulates a significant aspect of modern electronics that has transformed our lives in numerous ways. From communication to computing and beyond, the impact of transistors is profound. As technology continues to evolve, the importance of transistor driven devices will only grow, paving the way for future innovations that enhance our everyday experiences. Understanding this term not only helps us appreciate the advancements in technology but also encourages us to explore the possibilities that lie ahead in the realm of electronics.

在电子世界中，术语transistor driven指的是利用晶体管作为主要组件进行放大和开关的设备和电路。晶体管是现代电子设备的基本构建块，能够以极高的精度控制电信号。它们因其体积小、可靠性高和功耗低而取代了大多数应用中的真空管。transistor driven技术的重要性可以在我们日常生活的各个方面看到，特别是在通信、计算和娱乐领域。 要理解transistor driven技术的影响，我们需要看一下它的历史背景。1947年，约翰·巴丁、沃尔特·布拉顿和威廉·肖克利发明的晶体管标志着电子学的革命性变化。在晶体管出现之前，真空管被用于收音机、电视和早期计算机，但它们笨重、易碎且消耗大量电力。晶体管的引入使得可以制造更小、更高效的设备，这些设备可以更好地工作并使用更长时间。这一转变为集成电路的发展铺平了道路，进一步微型化电子元件，并导致现代计算机和智能手机的诞生。 transistor driven设备最显著的优势之一是其放大电信号的能力。例如，在音频设备中，晶体管用于增强声音信号，实现高质量的音乐播放。同样，在无线电发射器中，晶体管帮助调制和放大信号，以便在长距离内清晰传输。这种能力改变了我们的交流方式，使我们能够拥有便携式设备，将我们全球连接起来。 此外，transistor driven技术的应用不仅限于音频和通信。在计算中，晶体管作为处理能力的基本单元。现代处理器包含数十亿个晶体管，所有这些晶体管共同工作以执行复杂的计算和运行程序。由于晶体管技术的进步，计算机的速度和效率得到了极大提高，使我们能够执行曾经无法想象的任务。从简单的计算到先进的人工智能，晶体管的作用不容小觑。 除了性能优势外，transistor driven设备在能效方面也优于其前身。随着对能源消耗和环境影响的关注加剧，对低功耗电子产品的需求也在增加。晶体管的功耗显著低于真空管，从而延长了便携设备的电池寿命，并降低了消费者的能源成本。这种效率在可持续实践日益成为优先事项的世界中至关重要。 此外，transistor driven技术的多功能性使各个领域的创新成为可能。例如，在医疗设备中，晶体管被用于诊断设备、监测系统，甚至生命救助设备如起搏器。能够在保持功能的同时微型化这些设备对于患者护理和治疗至关重要。 总之，术语transistor driven概括了现代电子学的一个重要方面，这一方面以无数种方式改变了我们的生活。从通信到计算及其他领域，晶体管的影响深远。随着技术的不断发展，transistor driven设备的重要性只会增加，为未来的创新铺平道路，提升我们的日常体验。理解这个术语不仅有助于我们欣赏技术进步，还鼓励我们探索电子领域未来的可能性。