miniaturize

简明释义

英[ˈmɪnətʃəraɪz]美[ˈmɪnətʃəraɪz]

v. 使小型化，使微型化；使成为缩影

第 三 人 称 单 数 m i n i a t u r i z e s

现 在 分 词 m i n i a t u r i z i n g

过 去 式 m i n i a t u r i z e d

过 去 分 词 m i n i a t u r i z e d

英英释义

单词用法

同义词

反义词

例句

1.Supported by institute 38 of CECT, a S-band miniaturize T/R module based on MCM technology is studied in this paper.

本课题结合中电科技集团38所的科研项目，研制了一种基于MCM技术的小型化S波段T/R组件，达到了良好的效果。

2.The good news is that the same technology that allowed miniaturization of electronics, is now allowing us to miniaturize biological laboratories.

好消息是，使电子产品微型化的同样技术，现在已可使我们的生物实验室微型化。

3.The present invention provides a thin film transistor in which a substantial length of a channel is shortened to miniaturize a semiconductor device and a manufacturing method thereof.

本发明提供一种薄膜晶体管及其制造方法，其中该晶体管的沟道的基本长度被缩短以微型化半导体装置。

4.This paper presents the theory limit on antennas' gain and bandwidth, as well as how to improve the bandwidth and miniaturize them, especially micro-strip antenna is elaborated.

本文讨论了天线带宽和增益的理论极限，以及如何提高天线带宽、实现小型化的各种方法，特别对微带贴片天线进行了介绍。

5.The advent of nanograss offered the possibility of making reserve batteries far easier to miniaturize .

奈米草的构想出现之后，将储备电池缩小的可能性也随之萌芽。

6.The filter is reduced in size and can be used to miniaturize the circuit.

该结构滤波器的尺寸显著减小，从而有利于实现电路的小型化。

7.The goal of this project is to miniaturize 微型化 the sensors without losing accuracy.

这个项目的目标是将传感器进行微型化而不失去准确性。

8.They managed to miniaturize 微型化 the drone, making it more portable.

他们成功地将无人机进行微型化，使其更便于携带。

9.The engineers worked hard to miniaturize 微型化 the components for the new smartphone.

工程师们努力将新智能手机的组件进行微型化。

10.The team aims to miniaturize 微型化 the battery technology for electric vehicles.

团队的目标是将电动车的电池技术进行微型化。

11.Scientists are trying to miniaturize 微型化 medical devices for easier implantation.

科学家们正在尝试将医疗设备进行微型化以便于植入。

作文

In today's rapidly advancing technological landscape, one of the most fascinating trends is the ability to miniaturize complex devices and systems. The concept of miniaturization refers to the process of making things smaller while retaining their functionality and performance. This phenomenon has revolutionized various industries, from consumer electronics to medical devices, and has had a profound impact on our daily lives.Take, for example, the evolution of mobile phones. In the early days, phones were bulky, heavy, and limited in functionality. However, with advancements in technology, manufacturers have been able to miniaturize components such as batteries, processors, and screens. As a result, we now carry powerful smartphones in our pockets that can perform tasks that once required a desktop computer. This shift towards miniaturization not only enhances portability but also improves user experience by providing more features in a compact form.Moreover, the field of medicine has greatly benefited from the ability to miniaturize medical equipment. Traditionally, diagnostic tools like MRI machines and ultrasound devices were large and expensive, limiting their accessibility. However, recent innovations have led to the development of portable diagnostic devices that can be easily transported and used in various settings. For instance, handheld ultrasound devices allow doctors to conduct examinations at the bedside, improving patient care and speeding up diagnosis. The miniaturization of medical technology has made healthcare more efficient and accessible, ultimately saving lives.The impact of miniaturization extends beyond just consumer electronics and healthcare. In the realm of computing, the miniaturization of transistors has enabled the development of faster and more powerful computers. Moore's Law, which states that the number of transistors on a microchip doubles approximately every two years, exemplifies this trend. As transistors become smaller, they consume less power and generate less heat, paving the way for more efficient computing solutions.However, the journey of miniaturization is not without its challenges. As devices become smaller, engineers face difficulties in managing heat dissipation, ensuring durability, and maintaining performance. Moreover, there are concerns regarding the environmental impact of producing smaller electronic devices, as they often contain hazardous materials that can be harmful if not disposed of properly. Therefore, it is crucial for manufacturers to adopt sustainable practices as they continue to miniaturize their products.In conclusion, the ability to miniaturize devices and systems has transformed various aspects of our lives, making technology more accessible and efficient. From smartphones to medical devices, miniaturization has opened up new possibilities and improved the quality of life for many. As we continue to innovate and push the boundaries of what is possible, it is essential to address the challenges that come with miniaturization to ensure a sustainable future. The journey of miniaturization is ongoing, and its potential is limitless, promising exciting advancements for generations to come.

在当今快速发展的技术环境中，最令人着迷的趋势之一是能够将复杂的设备和系统进行微型化。微型化的概念指的是在保留功能和性能的情况下，使事物变得更小。这一现象彻底改变了各个行业，从消费电子到医疗设备，对我们的日常生活产生了深远的影响。以手机的发展为例。在早期，电话笨重、沉重且功能有限。然而，随着技术的进步，制造商能够对电池、处理器和屏幕等组件进行微型化。因此，我们现在口袋里携带的强大智能手机能够执行曾经需要台式计算机才能完成的任务。这种向微型化的转变不仅增强了便携性，还通过在紧凑的形式中提供更多功能来改善用户体验。此外，医疗领域也极大受益于医疗设备的微型化。传统上，MRI机器和超声波设备等诊断工具体积庞大且昂贵，限制了其可及性。然而，最近的创新导致了便携式诊断设备的发展，这些设备可以轻松运输并在各种环境中使用。例如，手持超声设备使医生能够在床边进行检查，提高了患者护理质量并加快了诊断速度。医疗技术的微型化使医疗服务更加高效和可及，最终拯救了生命。微型化的影响不仅限于消费电子和医疗。在计算领域，晶体管的微型化使得更快、更强大的计算机的发展成为可能。摩尔定律指出，微芯片上的晶体管数量每两年大约翻一番，体现了这一趋势。随着晶体管变得更小，它们消耗的电力更少，产生的热量也更少，为更高效的计算解决方案铺平了道路。然而，微型化的旅程并非没有挑战。随着设备变得更小，工程师面临着管理热散发、确保耐用性和维护性能的困难。此外，生产更小的电子设备对环境的影响也引起了关注，因为它们通常含有在不当处置时可能有害的危险材料。因此，制造商在继续微型化产品时，采取可持续的做法至关重要。总之，能够微型化设备和系统的能力已改变了我们生活的各个方面，使技术变得更加可及和高效。从智能手机到医疗设备，微型化开辟了新的可能性，提高了许多人的生活质量。随着我们不断创新并推动可能性的边界，解决伴随微型化而来的挑战以确保可持续的未来显得尤为重要。微型化的旅程仍在继续，其潜力是无限的，承诺为未来几代人带来激动人心的进展。