cybernetic
简明释义
英[ˌsaɪbəˈnetɪk]美[ˌsaɪbərˈnetɪk]
adj. 控制论的
英英释义
单词用法
控制生物体 | |
控制论控制 | |
控制论方法 | |
控制论模型 | |
控制网络 | |
控制通信 |
同义词
反义词
例句
1.He was nearly killed in the battle, and seventy-five percent of Teshik's body required cybernetic replacements.
泰希克在这一战中几乎战死,他身体75%的部分需要以机械代替。
2.Now the systemic, cybernetic and information processing methods have been widely used by biologist to observe and understand the biology process.
生物学家用系统、控制论与信息处理方法来观察了解生物学过程的例子越来越多。
3.In place of physical formations are cybernetic organizations capable of tapping into combat power on a global scale.
取代实际阵形的是在全球范围内投送战斗力量的组织控制能力。
4.The second chapter explains how to constitute relevant accounting control system based on cybernetic theories, from the aspects of environment, elements, forms, criterions and appraising system .
第二部分从会计控制系统的环境、要素、形式、规范、评价体系等几个方面,说明如何基于控制沦原理建立相应的会计控制系统。
5.He also encourages the application of cybernetic chemistry to explain the complicated chemical phenomena by using simple but effective rules.
他还推动了控制论化学的应用,对化学中的许多疑难繁琐的现象给出清晰满意的解释。
6.Authors combine financial theory with cybernetics and system theory to prove and elucidate a new bank management method: the cybernetic system of commercial bank asset liability ratios management.
作者将金融理论、控制论、系统论有机地结合起来,提出并论证了一种新的银行管理方法:商业银行资产负债比例管理控制论系统。
7.The application course, general compose, function action of loop electricity cybernetic system for cold rolling mill are been explained and the application examples are given.
说明了活套电控系统在冷轧厂整个生产中的应用过程、总体组成及各功能块的作用,给出了应用实例。
8.Such cybernetic jests would probably be even funnier than when cracked by a human being, especially the ones I know.
这些在电脑控制下讲出的笑话甚至可能比人类讲出来的更好笑,尤其是与我知道的笑话相比。
9.In this thesis, through the analysis on mass balance and energy balance in the dense phase and sparse phase, the bed temperature cybernetic model is established in this thesis.
本文通过对循环流化床锅炉密相区和稀相区的质量平衡与能量平衡的分析,建立了床温控制模型。
10.Researchers are exploring cybernetic 控制论 models to improve human-computer interaction.
研究人员正在探索控制论模型,以改善人机交互。
11.The field of cybernetic 控制论 systems has revolutionized automation in manufacturing.
控制论系统的领域已经彻底改变了制造业的自动化。
12.In a cybernetic 控制论 approach, feedback loops are essential for system stability.
在控制论方法中,反馈回路对于系统的稳定性至关重要。
13.Students in the cybernetic 控制论 engineering program learn about system dynamics.
控制论工程专业的学生学习系统动态。
14.The concept of cybernetic 控制论 organisms helps us understand complex ecosystems.
控制论有机体的概念帮助我们理解复杂的生态系统。
作文
In the modern era, technology is advancing at an unprecedented rate, and one of the most fascinating fields that has emerged is that of cybernetic (控制论). This interdisciplinary domain combines concepts from engineering, biology, computer science, and philosophy to understand and design systems that can self-regulate and adapt to their environment. The term 'cybernetics' was first coined by Norbert Wiener in the 1940s, and it has since evolved to encompass a wide range of applications, from robotics to artificial intelligence. The essence of cybernetic (控制论) systems lies in their ability to process information and feedback. For instance, consider a simple thermostat. It monitors the temperature of a room and adjusts the heating or cooling system accordingly to maintain a desired temperature. This feedback loop is a fundamental principle of cybernetic (控制论) systems, where the output is continuously adjusted based on the input received. Such systems are not only limited to mechanical devices but also extend to biological organisms. In nature, animals and humans display cybernetic (控制论) behaviors through their nervous systems. For example, when a person touches a hot surface, sensory receptors send signals to the brain, which then processes this information and triggers a reflex action to withdraw the hand. This intricate process showcases how living beings utilize cybernetic (控制论) principles to survive and interact with their surroundings. The implications of cybernetic (控制论) theory stretch far beyond simple feedback mechanisms. In the realm of artificial intelligence, cybernetic (控制论) principles are foundational for creating intelligent machines that learn from their experiences. Machine learning algorithms, for instance, rely on feedback loops to improve their performance over time. By analyzing data and adjusting their models based on outcomes, these systems embody the core ideas of cybernetic (控制论) theory. Moreover, cybernetic (控制论) concepts have been applied to complex social systems, including organizations and economies. Understanding these systems through a cybernetic (控制论) lens allows us to identify patterns and behaviors that can lead to more effective management and decision-making. For example, organizations can be viewed as cybernetic (控制论) systems where various departments communicate and adjust to ensure overall efficiency. As we move forward into an increasingly interconnected world, the relevance of cybernetic (控制论) principles will only grow. With the rise of the Internet of Things (IoT), smart devices are becoming ubiquitous, and they rely on cybernetic (控制论) feedback loops to function effectively. These devices collect data, analyze it, and make decisions in real-time, showcasing the practical application of cybernetic (控制论) theories in everyday life. In conclusion, cybernetic (控制论) is a vital field that bridges various disciplines and offers insights into the functioning of both natural and artificial systems. Its principles of feedback and adaptation are essential for understanding how complex systems operate and evolve. As we continue to innovate and integrate technology into our lives, the study of cybernetic (控制论) will remain crucial for navigating the challenges and opportunities that lie ahead.
在现代时代,科技以空前的速度发展,而出现的最令人着迷的领域之一就是控制论(cybernetic)。这个跨学科领域结合了工程学、生物学、计算机科学和哲学的概念,以理解和设计能够自我调节和适应其环境的系统。‘控制论’一词最早是在20世纪40年代由诺伯特·维纳提出的,之后它的发展涵盖了从机器人技术到人工智能的广泛应用。控制论(cybernetic)系统的本质在于其处理信息和反馈的能力。例如,考虑一个简单的恒温器。它监测房间的温度,并相应地调整供热或制冷系统,以维持所需的温度。这个反馈循环是控制论(cybernetic)系统的基本原则,其中输出根据接收到的输入不断调整。这些系统不仅限于机械设备,还扩展到生物有机体。在自然界中,动物和人类通过他们的神经系统表现出控制论(cybernetic)行为。例如,当一个人触摸到热表面时,感官受体会向大脑发送信号,大脑处理这些信息并触发反射动作以撤回手。这一复杂的过程展示了生物如何利用控制论(cybernetic)原则来生存和与周围环境互动。控制论(cybernetic)理论的影响远不止于简单的反馈机制。在人工智能领域,控制论(cybernetic)原则是创建能够从经验中学习的智能机器的基础。例如,机器学习算法依赖于反馈循环来提高其性能。通过分析数据并根据结果调整模型,这些系统体现了控制论(cybernetic)理论的核心思想。此外,控制论(cybernetic)概念已被应用于复杂的社会系统,包括组织和经济。通过控制论(cybernetic)视角理解这些系统使我们能够识别模式和行为,从而导致更有效的管理和决策。例如,组织可以被视为控制论(cybernetic)系统,各个部门之间进行沟通和调整,以确保整体效率。随着我们进入一个日益互联的世界,控制论(cybernetic)原则的相关性只会增加。随着物联网(IoT)的兴起,智能设备变得无处不在,而它们依赖于控制论(cybernetic)反馈循环来有效运作。这些设备收集数据、分析数据并实时做出决策,展示了控制论(cybernetic)理论在日常生活中的实际应用。总之,控制论(cybernetic)是一个重要的领域,连接了多个学科,并提供了对自然和人工系统功能的洞察。其反馈和适应的原则对于理解复杂系统的运作和演变至关重要。随着我们继续创新并将技术融入我们的生活,研究控制论(cybernetic)将对应对未来的挑战和机遇保持至关重要。
