super-large-scale integration

简明释义

超大规模集成电路

英英释义

例句

1.In automotive electronics, super-large-scale integration is crucial for enhancing safety features.

在汽车电子中，超大规模集成对增强安全功能至关重要。

2.Engineers are focusing on super-large-scale integration to reduce the size of circuit boards.

工程师们正在专注于超大规模集成以减少电路板的尺寸。

3.The field of robotics greatly benefits from super-large-scale integration technologies.

机器人领域从超大规模集成技术中受益匪浅。

4.With advancements in super-large-scale integration, we can now create more powerful computing devices.

随着超大规模集成技术的进步，我们现在可以制造出更强大的计算设备。

5.The latest smartphones utilize super-large-scale integration to pack more features into smaller chips.

最新的智能手机利用超大规模集成将更多功能压缩到更小的芯片中。

作文

In the modern world, technology is constantly evolving, and one of the most significant advancements in this field is the concept of super-large-scale integration. This term refers to the process of integrating thousands or even millions of transistors onto a single chip, which has revolutionized the way we design and manufacture electronic devices. The implications of super-large-scale integration are profound, affecting everything from consumer electronics to industrial applications.To understand the impact of super-large-scale integration, it is essential to look at its historical context. In the early days of computing, circuits were built using discrete components, which made them bulky and inefficient. As technology progressed, engineers developed integrated circuits (ICs) that allowed multiple components to be combined into a single unit. This innovation paved the way for the development of large-scale integration (LSI) and eventually super-large-scale integration. The primary advantage of super-large-scale integration is its ability to reduce the size and cost of electronic devices while simultaneously improving performance. By packing more transistors into a smaller area, manufacturers can create faster and more powerful chips. This has led to the miniaturization of devices such as smartphones, tablets, and laptops, making them more accessible to consumers and enhancing their functionality.Moreover, super-large-scale integration has enabled the development of complex systems-on-chip (SoCs), which integrate all the necessary components of a computer system onto a single chip. This includes the central processing unit (CPU), graphics processing unit (GPU), memory, and even communication interfaces. SoCs have become a cornerstone of modern electronics, allowing for greater efficiency and lower power consumption.However, with these advancements come challenges. The increasing complexity of super-large-scale integration designs requires sophisticated tools and techniques for verification and testing. As the number of transistors on a chip continues to grow, ensuring that they function correctly becomes a daunting task. Engineers must develop new methodologies to manage this complexity, including advanced simulation techniques and automated testing processes.Another challenge associated with super-large-scale integration is heat dissipation. As more transistors are packed into a chip, the amount of heat generated increases, which can lead to overheating and potential failure. To combat this, engineers are exploring new materials and cooling techniques to ensure that chips can operate efficiently without compromising performance.In conclusion, super-large-scale integration has transformed the landscape of electronics, enabling the creation of powerful, compact devices that have become integral to our daily lives. While there are challenges to overcome, the benefits of this technology are undeniable. As we continue to push the boundaries of what is possible with super-large-scale integration, we can expect to see even more innovative applications emerge in the future, further enhancing our technological capabilities and shaping the world around us.

在现代世界中，技术不断发展，其中一个最重要的进步是“超大规模集成”（super-large-scale integration）的概念。这个术语指的是将成千上万甚至数百万个晶体管集成到单个芯片上的过程，这彻底改变了我们设计和制造电子设备的方式。“超大规模集成”（super-large-scale integration）的影响深远，影响着从消费电子产品到工业应用的方方面面。要理解“超大规模集成”（super-large-scale integration）的影响，必须了解其历史背景。在计算机发展的早期，电路是由离散元件构建的，这使得它们笨重且效率低下。随着技术的进步，工程师们开发了集成电路（IC），允许将多个组件组合成一个单元。这一创新为大规模集成（LSI）和最终的“超大规模集成”（super-large-scale integration）的发展铺平了道路。“超大规模集成”（super-large-scale integration）的主要优势在于能够减少电子设备的尺寸和成本，同时提高性能。通过将更多的晶体管压缩到更小的区域，制造商可以创建更快、更强大的芯片。这导致了智能手机、平板电脑和笔记本电脑等设备的小型化，使它们对消费者更具可及性，并增强了其功能。此外，“超大规模集成”（super-large-scale integration）还使复杂的系统芯片（SoC）的开发成为可能，该芯片将计算机系统所需的所有组件集成到单个芯片上。这包括中央处理器（CPU）、图形处理器（GPU）、内存，甚至通信接口。SoC已成为现代电子产品的基石，允许更高的效率和更低的功耗。然而，随着这些进步而来的挑战也不容忽视。“超大规模集成”（super-large-scale integration）设计的日益复杂性需要复杂的工具和技术来进行验证和测试。随着芯片上晶体管数量的不断增长，确保它们正常工作变得异常艰巨。工程师们必须开发新的方法来管理这种复杂性，包括先进的仿真技术和自动化测试流程。与“超大规模集成”（super-large-scale integration）相关的另一个挑战是热量散发。随着越来越多的晶体管被压缩到一个芯片上，产生的热量也增加，这可能导致过热和潜在的故障。为了应对这一问题，工程师们正在探索新材料和冷却技术，以确保芯片能够高效运行而不妨碍性能。总之，“超大规模集成”（super-large-scale integration）彻底改变了电子产品的格局，使强大而紧凑的设备成为我们日常生活中不可或缺的一部分。尽管面临挑战，但这一技术的好处是不可否认的。随着我们继续推动“超大规模集成”（super-large-scale integration）的可能性，我们可以期待看到更多创新应用的出现，进一步增强我们的技术能力并塑造我们周围的世界。