miniaturise
简明释义
英[ˈmɪn.i.ə.tʃər.aɪz]美[ˈmɪn.i.ə.tʃər.aɪz]
v. 使小型化(等于 miniaturize)
第 三 人 称 单 数 m i n i a t u r i s e s
现 在 分 词 m i n i a t u r i s i n g
过 去 式 m i n i a t u r i s e d
过 去 分 词 m i n i a t u r i s e d
英英释义
将某物制作成非常小的比例或尺寸。 | |
To reduce the size of something while retaining its essential features. | 在保留其基本特征的同时减少某物的大小。 |
单词用法
同义词
反义词
| 放大 | The scientist used a microscope to magnify the tiny details of the specimen. | 科学家使用显微镜放大标本的微小细节。 | |
| 扩展 | 我们需要将这张图片放大以用于演示。 |
例句
1.However, Cambridge Design Partnership is confident that it can miniaturise the system further based on its experience of developing medical equipment for civilian ambulance crews.
同时,剑桥设计公司有信心将该系统进一步小型化,并将其作为基础医疗设备配备给救生人员使用。
2.However, Cambridge Design Partnership is confident that it can miniaturise the system further based on its experience of developing medical equipment for civilian ambulance crews.
同时,剑桥设计公司有信心将该系统进一步小型化,并将其作为基础医疗设备配备给救生人员使用。
3.The goal of this project is to miniaturise 微型化 the drone technology for personal use.
这个项目的目标是将无人机技术微型化以供个人使用。
4.The team was able to miniaturise 微型化 the camera without losing image quality.
团队能够在不损失图像质量的情况下将相机微型化。
5.Scientists are trying to miniaturise 微型化 medical devices to make them less invasive.
科学家们正在尝试微型化医疗设备,以使其更少侵入性。
6.The engineers worked hard to miniaturise 微型化 the components for the new smartphone.
工程师们努力将新智能手机的组件微型化。
7.They plan to miniaturise 微型化 the satellite components to reduce launch costs.
他们计划将卫星组件微型化以降低发射成本。
作文
In today's rapidly evolving technological landscape, the ability to miniaturise devices has become a hallmark of innovation. From smartphones to medical equipment, the trend towards smaller and more efficient technology is reshaping our daily lives. The process of miniaturising components not only enhances portability but also improves functionality, making it essential in various fields such as electronics, healthcare, and even space exploration.One of the most notable examples of miniaturisation can be seen in the evolution of mobile phones. Just a few decades ago, mobile phones were bulky and cumbersome, often requiring a large battery and numerous components that took up significant space. However, with advancements in technology, engineers have learned to miniaturise these elements, allowing for sleek designs that fit comfortably in our pockets. Today’s smartphones are equipped with powerful processors, high-resolution cameras, and extensive storage, all while being incredibly compact. This shift towards miniaturisation has revolutionised communication, enabling us to connect with others instantly, regardless of distance.Another critical area where miniaturisation plays a vital role is in the field of medicine. Medical devices such as pacemakers and insulin pumps have undergone significant transformations through miniaturisation. These devices are now smaller, more efficient, and less invasive, greatly improving patient comfort and quality of life. For instance, modern pacemakers can be implanted with minimal incisions, thanks to their reduced size, allowing patients to recover faster and return to their normal activities sooner. Moreover, the miniaturisation of diagnostic tools, like portable ultrasound machines, has made it possible for healthcare professionals to provide immediate care in various settings, from hospitals to remote locations.The implications of miniaturisation extend beyond consumer electronics and healthcare; they also reach into the realm of space exploration. As we aim to explore further into our solar system and beyond, the need for lightweight and compact equipment becomes increasingly important. Engineers are continually working to miniaturise instruments and sensors used in spacecraft, allowing for more efficient use of space and resources. This miniaturisation not only reduces launch costs but also enables the deployment of multiple instruments on a single mission, enhancing our ability to gather data and explore new frontiers.However, miniaturisation does not come without its challenges. As components become smaller, issues such as heat dissipation and power consumption become more pronounced. Engineers must find innovative solutions to manage these challenges while still achieving the desired level of performance. Furthermore, there is a constant push to ensure that miniaturised devices maintain their reliability and safety standards, especially in critical applications like healthcare.In conclusion, the ability to miniaturise technology has transformed how we live, work, and interact with the world around us. From enhancing communication through compact smartphones to improving patient care with smaller medical devices, the impact of miniaturisation is profound. As we continue to push the boundaries of what is possible, it is clear that miniaturisation will remain a key driver of innovation, paving the way for a more efficient and connected future.
在当今快速发展的技术环境中,设备的小型化能力已成为创新的标志。从智能手机到医疗设备,向更小、更高效技术的趋势正在重塑我们的日常生活。小型化组件的过程不仅增强了便携性,还提高了功能性,使其在电子、医疗和太空探索等多个领域变得至关重要。最显著的小型化例子可以在移动电话的发展中看到。几十年前,移动电话笨重且繁琐,通常需要一个大电池和许多占用大量空间的组件。然而,随着技术的进步,工程师们学会了小型化这些元素,使得设计更加流线型,能够舒适地放在口袋里。今天的智能手机配备了强大的处理器、高分辨率的摄像头和广泛的存储,同时又极其紧凑。这种向小型化的转变彻底改变了通信,使我们能够即时与他人联系,无论距离多远。小型化发挥重要作用的另一个关键领域是医学。诸如心脏起搏器和胰岛素泵等医疗设备通过小型化经历了重大转变。这些设备现在更小、更高效、侵入性更小,大大改善了患者的舒适度和生活质量。例如,现代心脏起搏器可以通过最小的切口植入,得益于其减小的体积,使患者能够更快恢复并更早恢复正常活动。此外,诊断工具(如便携式超声波机)的小型化使医疗专业人员能够在各种环境中提供即时护理,从医院到偏远地区。小型化的影响不仅限于消费电子产品和医疗保健;它们还延伸到太空探索领域。随着我们旨在进一步探索我们的太阳系及其以外的地方,轻量级和紧凑设备的需求变得越来越重要。工程师们不断努力小型化用于航天器的仪器和传感器,从而更有效地利用空间和资源。这种小型化不仅减少了发射成本,还使得在一次任务中部署多个仪器成为可能,增强了我们收集数据和探索新前沿的能力。然而,小型化并非没有挑战。随着组件变得更小,散热和功耗等问题变得更加明显。工程师们必须找到创新的解决方案来管理这些挑战,同时仍然实现所需的性能水平。此外,始终有一种推动力,以确保小型化设备保持其可靠性和安全标准,特别是在医疗等关键应用中。总之,小型化技术的能力改变了我们生活、工作和与周围世界互动的方式。从通过紧凑的智能手机增强通信,到通过更小的医疗设备改善患者护理,小型化的影响深远。随着我们继续突破可能的界限,显然小型化将继续成为创新的主要驱动力,为更高效和互联的未来铺平道路。
