microcircuit

简明释义

英[ˈmaɪkrə(ʊ)ˌsɜːkɪt]美[ˈmaɪkrəˌsɜːrkɪt]

n. [电子] 微电路

英英释义

单词用法

同义词

反义词

例句

1.CMX649 is an excellent CVSD-based voice codec manufactured by CML Microcircuit, which is applicable in a wide range of voice coding applications, especially in wireless applications.

CMX649能够成功地应用在广泛的语音编码系统中，尤其适合无线语音系统应用。

2.CMX649 is an excellent CVSD-based voice codec manufactured by CML Microcircuit, which is applicable in a wide range of voice coding applications, especially in wireless applications.

CMX649能够成功地应用在广泛的语音编码系统中，尤其适合无线语音系统应用。

3.New adapter USES the created by company custom-made microcircuit (ASIC) whereas, previously Sun bought 10 gigabit controllers in S2IO.

新的网路卡使用所造成的公司订制型微电路(ASIC的)，而先前孙买了10千兆位控制器在s2io。

4.The control chart being core tool of SPC technology and its application in microcircuit manufacture are described in detail.

详细叙述了SPC技术的核心工具控制图技术及其在微电路生产中的应用。

5.IC technology is microcircuit or system of introducing specific technology and is based on semiconductor material.

IC技术是指以半导体晶体材料为基础，采用专门工艺技术组成的微小型电路或系统。

6.Metal Migration has been the cause of many catastrophic microcircuit failures.

金属迁移能导致混合微电路发生灾难性失效。

7.The method could also be used for other microcircuit processes.

所讨论的方法可用于其他微电路工艺设备的表征。

8.The engineer designed a new microcircuit to improve the efficiency of the device.

工程师设计了一种新的微电路以提高设备的效率。

9.Advancements in microcircuit technology have enabled faster computing speeds.

在微电路技术方面的进步使得计算速度更快。

10.The microcircuit in my smartphone is responsible for processing all tasks.

我手机中的微电路负责处理所有任务。

11.Researchers are developing a microcircuit that can operate at lower power levels.

研究人员正在开发一种可以在较低功率下运行的微电路。

12.The microcircuit used in medical devices needs to be extremely reliable.

用于医疗设备的微电路需要非常可靠。

作文

In today's rapidly advancing technological landscape, the term microcircuit (微电路) has become increasingly prevalent. A microcircuit is a tiny electronic circuit that is fabricated onto a small piece of semiconductor material, typically silicon. These circuits are integral to modern electronics, powering everything from smartphones to sophisticated medical devices. The evolution of microcircuits has been remarkable, transforming the way we live and interact with technology. The history of microcircuits can be traced back to the mid-20th century when the first transistors were developed. These transistors paved the way for the creation of integrated circuits, which combined multiple electronic components into a single chip. This innovation drastically reduced the size and cost of electronic devices, making them more accessible to the general public. Over the years, advancements in fabrication techniques have allowed engineers to create increasingly smaller and more efficient microcircuits, leading to the miniaturization of technology. One of the most significant impacts of microcircuits is their role in the development of computers. Early computers were large, cumbersome machines that required vast amounts of space and power. However, with the advent of microcircuits, computers became smaller, faster, and more powerful. Today, we carry more computing power in our pockets than was available to entire research facilities just a few decades ago. This transformation has revolutionized industries, enabling advancements in fields such as artificial intelligence, data analysis, and telecommunications. Moreover, the impact of microcircuits extends beyond personal computing. In the medical field, microcircuits are used in devices such as pacemakers, insulin pumps, and diagnostic equipment. These applications demonstrate how microcircuits can enhance the quality of life for individuals with chronic health conditions. By enabling precise monitoring and control of medical therapies, microcircuits play a crucial role in modern healthcare. The environmental implications of microcircuits are also worth considering. As the demand for electronic devices continues to grow, so does the need for sustainable manufacturing practices. Engineers and scientists are now exploring ways to create microcircuits that are not only efficient but also environmentally friendly. This includes the development of biodegradable materials and energy-efficient production methods. By addressing these challenges, the industry can ensure that the benefits of microcircuits do not come at the expense of the planet. In conclusion, the significance of microcircuits (微电路) in our daily lives cannot be overstated. From revolutionizing computing to enhancing medical technology, microcircuits have transformed the world in countless ways. As technology continues to evolve, so too will the role of microcircuits in shaping our future. It is essential for us to appreciate and understand the profound impact these tiny circuits have on our lives and to continue pushing the boundaries of what is possible through innovation.

在当今快速发展的技术环境中，术语microcircuit（微电路）变得越来越普遍。microcircuit是一个微小的电子电路，通常被制造在一小块半导体材料上，通常是硅。这些电路是现代电子产品的重要组成部分，为从智能手机到复杂医疗设备的一切提供动力。microcircuit的发展历程令人瞩目，改变了我们生活和与技术互动的方式。 microcircuit的历史可以追溯到20世纪中期，当时第一个晶体管被开发出来。这些晶体管为集成电路的创建铺平了道路，集成电路将多个电子元件结合到一个芯片中。这一创新大幅减少了电子设备的尺寸和成本，使其更易于普通大众获取。随着制造技术的进步，工程师们能够创造出越来越小、效率更高的microcircuits，导致技术的微型化。 microcircuits最显著的影响之一是它们在计算机发展中的作用。早期的计算机是大型笨重的机器，需要大量的空间和电力。然而，随着microcircuits的出现，计算机变得更小、更快、更强大。今天，我们口袋里的计算能力超过了几十年前整个研究设施所能提供的。这一转变彻底革新了各个行业，使人工智能、数据分析和电信等领域的进步成为可能。 此外，microcircuits的影响还超越了个人计算。在医疗领域，microcircuits被用于起搏器、胰岛素泵和诊断设备等装置中。这些应用展示了microcircuits如何提升慢性病患者的生活质量。通过实现对医疗治疗的精确监测和控制，microcircuits在现代医疗保健中扮演着至关重要的角色。 microcircuits的环境影响同样值得关注。随着对电子设备需求的持续增长，对可持续制造实践的需求也在增加。工程师和科学家们现在正在探索创造不仅高效而且环保的microcircuits的方法。这包括开发可生物降解的材料和节能的生产方法。通过解决这些挑战，行业可以确保microcircuits的好处不会以牺牲地球为代价。 总之，microcircuits（微电路）在我们日常生活中的重要性不容小觑。从革命性的计算到增强医疗技术，microcircuits在无数方面改变了世界。随着技术的不断发展，microcircuits在塑造我们未来中的角色也将继续演变。我们必须欣赏和理解这些微小电路对我们生活的深远影响，并继续通过创新推动可能性的边界。