modelling

简明释义

英[ˈmɒdəlɪŋ]美[ˈmɑːdəlɪŋ]

n. 模化；立体感；模特儿职业（等于 modeling）

v. 模仿（model 的 ing 形式）；做模型

英英释义

单词用法

同义词

反义词

例句

1.Tullio has been modelling for Sandra for eleven years.

图利奥已经为桑德拉当了11年的模特儿。

2.She was being offered a modelling contract.

她得到一份当模特儿的合同。

3.This was modelling at its most feeble.

这便是金融建模最致命的要害所在。

4.You have been modelling yourself on others all your life.

你一辈子都在以别人为榜样。

5.So is figure modelling worth the hassle?

那么人体模特值得这么冒险吗？

6.BPMN is currently adopted as a modelling notation.

BPMN目前被作为一种建模符号使用。

7.Anna is a rising star in the world of modelling.

安娜是模特行业的后起之秀。

8.In science classes, we often use modelling 建模 to demonstrate complex theories.

在科学课上，我们经常使用建模来演示复杂理论。

9.The engineer is modelling 建模 the stress distribution in the bridge structure.

工程师正在对桥梁结构的应力分布进行建模。

10.We need to start modelling 建模 our data to predict future trends.

我们需要开始对数据进行建模以预测未来趋势。

11.The fashion designer spent hours modelling 造型 the dresses on a mannequin.

时装设计师花了几个小时在模特上进行裙子的造型。

12.The architect is focused on modelling 建模 the new building design using advanced software.

建筑师专注于使用先进软件进行新建筑设计的建模。

作文

In the realm of education and science, modelling plays a crucial role in helping us understand complex systems and phenomena. The term modelling refers to the process of creating representations of real-world situations or systems. These representations can be physical, mathematical, or conceptual, and they serve as tools for analysis and prediction. For instance, in physics, scientists often use mathematical modelling to simulate the behavior of particles under various conditions. By doing so, they can test theories and make predictions about how these particles will behave in the real world.Moreover, modelling is not limited to the sciences; it is also prevalent in fields such as economics, engineering, and even social sciences. In economics, economists create economic models to analyze market behaviors and predict future trends. These models help policymakers make informed decisions that can impact the economy. Similarly, engineers use modelling to design structures, ensuring they can withstand environmental forces such as wind and earthquakes. By creating detailed models, engineers can identify potential weaknesses and improve their designs before actual construction begins.In addition to its application in scientific and technical fields, modelling also has significant implications in the arts. Artists often use modelling techniques to create three-dimensional representations of their work. For example, sculptors might create clay models before producing the final piece in marble or bronze. This process allows artists to experiment with form and structure, refining their ideas before committing to the final material.Furthermore, modelling is an essential skill in education. Teachers often use modelling strategies to demonstrate concepts to students. For instance, in mathematics, a teacher might use visual aids to model a problem-solving process, allowing students to see the steps involved in reaching a solution. This approach not only enhances understanding but also encourages students to develop their modelling skills by creating their own representations of problems.The digital age has further transformed the way we engage with modelling. With advancements in technology, we now have access to sophisticated software that allows for more accurate and dynamic modelling. For example, computer simulations can model weather patterns, providing invaluable data for meteorologists. These simulations help us prepare for natural disasters and understand climate change better. Additionally, in the field of medicine, modelling is used to simulate the effects of drugs on the human body, leading to more effective treatments and therapies.In conclusion, modelling is a multifaceted concept that spans various disciplines. Whether in science, engineering, art, or education, modelling serves as a vital tool for understanding and interacting with the world around us. As we continue to advance technologically, the importance of modelling will only grow, providing us with the means to tackle complex challenges and innovate solutions. Embracing the principles of modelling can lead to greater insights and advancements in our understanding of both the natural and artificial worlds.

在教育和科学领域，建模在帮助我们理解复杂系统和现象方面发挥着至关重要的作用。术语建模指的是创建现实世界情境或系统表现的过程。这些表现可以是物理的、数学的或概念性的，作为分析和预测的工具。例如，在物理学中，科学家常常使用数学建模来模拟粒子在各种条件下的行为。通过这样做，他们可以测试理论并预测这些粒子在现实世界中的表现。此外，建模不仅限于科学；它在经济学、工程学甚至社会科学等领域也很普遍。在经济学中，经济学家创建经济模型以分析市场行为并预测未来趋势。这些模型帮助政策制定者做出可能影响经济的明智决策。同样，工程师使用建模来设计结构，以确保它们能够抵御风和地震等环境力量。通过创建详细的模型，工程师可以识别潜在的弱点，并在实际施工开始之前改善他们的设计。除了在科学和技术领域的应用外，建模在艺术中也具有重要意义。艺术家经常使用建模技术来创建其作品的三维表现。例如，雕塑家可能会在用大理石或青铜制作最终作品之前创建粘土模型。这个过程使艺术家能够实验形式和结构，在最终材料上做出承诺之前完善他们的想法。此外，建模在教育中也是一项重要技能。教师经常使用建模策略向学生演示概念。例如，在数学中，教师可能会使用视觉辅助工具来建模问题解决过程，使学生能够看到达成解决方案所涉及的步骤。这种方法不仅增强了理解，还鼓励学生通过创建自己问题的表现来发展他们的建模技能。数字时代进一步改变了我们与建模互动的方式。随着技术的进步，我们现在可以访问先进的软件，这使得更准确和动态的建模成为可能。例如，计算机模拟可以模拟天气模式，为气象学家提供宝贵的数据。这些模拟帮助我们为自然灾害做准备，并更好地理解气候变化。此外，在医学领域，建模被用来模拟药物对人体的影响，从而导致更有效的治疗和疗法。总之，建模是一个跨越多个学科的多面概念。无论是在科学、工程、艺术还是教育中，建模都是理解和与周围世界互动的重要工具。随着我们在技术上的不断进步，建模的重要性只会增加，为我们应对复杂挑战和创新解决方案提供手段。接受建模的原则可以带来更大的见解和在我们对自然和人造世界理解中的进步。