mechatronics
简明释义
英[ˌmekəˈtrɒnɪks]美[ˌmekəˈtrɑːnɪks]
n. 机电一体化;机械电子学
英英释义
单词用法
机电一体化设计 | |
机电一体化应用 | |
机电一体化组件 | |
机电一体化技术 | |
机电一体化实验室 | |
机电一体化课程 | |
机电一体化项目 | |
机电一体化研究 |
同义词
反义词
| 机械学 | Mechanics is the branch of physics that deals with the motion of objects. | 机械学是研究物体运动的物理学分支。 | |
| 电子学 | Electronics focuses on the behavior and movement of electrons in devices. | 电子学专注于电子在设备中的行为和运动。 |
例句
1.And a group of senior mechatronics technology elite.
还有一批资深的机电一体化技术精英。
2.This paper studied mainly the conceptual design of mechatronics system.
主要研究了机电一体化系统的概念设计。
3.Currently, the country engaged in "mechatronics" research and development and production of many units.
目前,我国从事“机电一体化”研究开发及生产的单位很多。
4.Mechatronics System Design is a course with strong practicality and comprehensiveness.
《机电一体化系统设计》是一门实践性和综合性都很强的课程。
5.It will also be of great use to roving frame mechatronics design in the future.
同时,对今后粗纱机的机电一体化打下了基础。
6.It combines mechatronics technology with orthopedics technology in Chinese medicine.
是现代机电技术和中医矫形技术有机结合的产品。
7.Currently, the country engaged in "mechatronics" research and development and production of many units.
目前,我国从事“机电一体化”研究开发及生产的单位很多。
8.Mechatronics design, small size, light weight, easy to use;
机电一体化设计,体积小,重量轻,使用方便;
9.Many modern robots are designed using principles of mechatronics 机电一体化 to enhance their functionality.
许多现代机器人使用机电一体化的原理来增强其功能。
10.The field of mechatronics 机电一体化 combines mechanical engineering, electronics, and computer science.
机电一体化领域结合了机械工程、电子学和计算机科学。
11.In the automotive industry, mechatronics 机电一体化 plays a crucial role in developing smart vehicles.
在汽车行业,机电一体化在开发智能车辆中发挥着关键作用。
12.The integration of mechatronics 机电一体化 has revolutionized manufacturing processes.
机电一体化的整合彻底改变了制造过程。
13.Students studying mechatronics 机电一体化 often work on projects involving automation systems.
学习机电一体化的学生通常会参与自动化系统的项目。
作文
In today's rapidly advancing technological landscape, the field of mechatronics is becoming increasingly significant. Mechatronics is a multidisciplinary area that combines mechanical engineering, electronics, computer science, and control engineering to design and create smart systems and products. This integration of various engineering disciplines allows for the development of innovative solutions that enhance efficiency and functionality in numerous applications.The term mechatronics originated in Japan in the 1960s and has since evolved into a vital component of modern engineering. It encompasses a wide range of technologies and applications, from robotics and automation to intelligent systems and smart devices. For instance, in the automotive industry, mechatronics plays a crucial role in the development of advanced driver-assistance systems (ADAS) that improve vehicle safety and performance. These systems rely on sensors, actuators, and control algorithms to enable features such as adaptive cruise control, lane-keeping assistance, and automatic emergency braking.Moreover, mechatronics is essential in the field of robotics, where it facilitates the creation of robots that can perform complex tasks with precision and adaptability. By integrating mechanical components with electronic systems and software, engineers can design robots that are capable of interacting with their environment, making decisions, and learning from experience. This has led to significant advancements in industries such as manufacturing, healthcare, and logistics, where robots are increasingly used to automate repetitive tasks and assist human workers.The impact of mechatronics extends beyond industrial applications; it also plays a vital role in everyday consumer products. For example, household appliances like washing machines, refrigerators, and microwaves have all benefited from mechatronics innovations. These appliances are equipped with sensors and microcontrollers that optimize their operation, resulting in improved energy efficiency and user convenience.Education and research in mechatronics are critical for fostering the next generation of engineers who will drive future innovations. Many universities now offer specialized programs in mechatronics, providing students with a comprehensive understanding of the principles and practices involved in this interdisciplinary field. Through hands-on projects and collaboration with industry partners, students gain valuable experience that prepares them for careers in various sectors, including aerospace, biomedical engineering, and renewable energy.As we look toward the future, the importance of mechatronics will only continue to grow. With the rise of the Internet of Things (IoT), artificial intelligence (AI), and smart manufacturing, the demand for skilled professionals in mechatronics will increase. These technologies rely heavily on the integration of mechanical systems with advanced electronics and software, making mechatronics expertise essential for developing the next generation of smart products and systems.In conclusion, mechatronics is a dynamic and evolving field that plays a crucial role in shaping our technological future. By combining the principles of mechanical engineering, electronics, and computer science, mechatronics enables the development of innovative solutions that enhance efficiency, safety, and convenience across various industries. As we continue to embrace technological advancements, the significance of mechatronics will undoubtedly expand, paving the way for new opportunities and challenges in engineering and beyond.
在当今快速发展的技术环境中,机电一体化领域变得越来越重要。机电一体化是一个多学科领域,结合了机械工程、电子学、计算机科学和控制工程,以设计和创造智能系统和产品。这种各工程学科的整合使得开发创新解决方案成为可能,从而在众多应用中提高效率和功能。机电一体化这个术语起源于20世纪60年代的日本,并且自那时以来已经演变为现代工程的重要组成部分。它涵盖了从机器人技术和自动化到智能系统和智能设备的广泛技术和应用。例如,在汽车工业中,机电一体化在高级驾驶辅助系统(ADAS)的开发中发挥了关键作用,这些系统提高了车辆的安全性和性能。这些系统依赖于传感器、执行器和控制算法,使得自适应巡航控制、车道保持辅助和自动紧急制动等功能成为可能。此外,机电一体化在机器人领域也是至关重要的,它促进了能够精确和灵活执行复杂任务的机器人的创建。通过将机械部件与电子系统和软件集成,工程师可以设计出能够与环境互动、做出决策并从经验中学习的机器人。这导致了制造、医疗和物流等行业的显著进步,在这些行业中,机器人越来越多地被用来自动化重复性任务并协助人类工人。机电一体化的影响超越了工业应用;它在日常消费产品中也发挥着重要作用。例如,洗衣机、冰箱和微波炉等家用电器都受益于机电一体化的创新。这些电器配备了传感器和微控制器,以优化其操作,从而提高能效和用户便利性。在机电一体化领域的教育和研究对于培养下一代工程师以推动未来的创新至关重要。许多大学现在提供机电一体化专业课程,为学生提供对这一跨学科领域原理和实践的全面理解。通过动手项目和与行业合作伙伴的合作,学生获得了宝贵的经验,为他们在航空航天、生物医学工程和可再生能源等各个行业的职业生涯做好准备。展望未来,机电一体化的重要性只会继续增长。随着物联网(IoT)、人工智能(AI)和智能制造的兴起,对机电一体化专业人才的需求将增加。这些技术在很大程度上依赖于机械系统与先进电子和软件的集成,使得机电一体化的专业知识成为开发下一代智能产品和系统的必需。总之,机电一体化是一个动态发展的领域,在塑造我们技术未来中发挥着关键作用。通过结合机械工程、电子学和计算机科学的原理,机电一体化使得开发创新解决方案成为可能,从而在各个行业中提高效率、安全性和便利性。随着我们继续拥抱技术进步,机电一体化的重要性无疑会扩大,为工程及其他领域带来新的机遇和挑战。
