reduced scale

简明释义

缩小叭例尺

英英释义

例句

1.For our project, we decided to create a reduced scale version of the park to analyze its layout.

为了我们的项目，我们决定制作公园的缩小比例版本，以分析其布局。

2.The architect presented a model of the building at a reduced scale to help visualize the design.

建筑师展示了一个建筑模型，采用了缩小比例，以帮助可视化设计。

3.In the science fair, students displayed their experiments using reduced scale models to save space.

在科学展上，学生们展示了他们的实验，使用缩小比例模型以节省空间。

4.The city planner created a reduced scale map to illustrate the proposed changes to traffic flow.

城市规划者制作了一张缩小比例地图，以说明提议的交通流变化。

5.The reduced scale model allowed us to test the wind flow around the structure efficiently.

这个缩小比例模型使我们能够有效地测试结构周围的风流。

作文

In recent years, the concept of a reduced scale has gained significant attention in various fields, including architecture, urban planning, and environmental science. The term refers to the practice of creating models or representations of larger systems at a smaller size, which allows for easier analysis and understanding of complex structures and processes. By examining these models, researchers and planners can identify potential issues and develop solutions without the need for extensive resources or time-consuming trials on full-scale projects.One notable application of reduced scale modeling is in the field of urban planning. City planners often utilize reduced scale models to visualize how new developments will fit into existing environments. This approach enables them to assess the impact of buildings on traffic flow, green spaces, and community dynamics. For instance, a city may create a reduced scale model of a proposed shopping center to evaluate its effects on local businesses and transportation systems. By doing so, planners can make informed decisions that promote sustainable growth and enhance the quality of life for residents.Additionally, in architecture, the use of reduced scale models allows architects to explore design concepts before committing to full-scale construction. These models serve as valuable tools for visualizing proportions, materials, and spatial relationships. By manipulating a reduced scale version of a building, architects can experiment with different configurations and aesthetics, ensuring that the final product meets both functional and artistic goals.Environmental scientists also benefit from reduced scale studies, particularly when investigating ecosystems or natural phenomena. By creating miniature versions of habitats, researchers can observe interactions between species and their environments under controlled conditions. This method provides insights into ecological dynamics that would be challenging to study in their natural, full-sized contexts. For example, a reduced scale model of a wetland can help scientists understand water filtration processes and the impact of pollutants on biodiversity.Moreover, the concept of reduced scale extends beyond physical modeling; it also applies to data analysis and simulation. In many scientific disciplines, researchers use algorithms and computational models to simulate real-world scenarios at a reduced scale. This approach allows for the examination of complex systems, such as climate change or economic trends, without the need for exhaustive data collection. By analyzing these simulations, scientists can predict outcomes and devise strategies to mitigate adverse effects.In conclusion, the idea of reduced scale is a powerful tool across various disciplines, enabling professionals to visualize, analyze, and innovate within their respective fields. Whether through physical models in architecture and urban planning or simulations in environmental science, reduced scale methodologies foster a deeper understanding of complex systems. As we continue to face global challenges, the importance of utilizing reduced scale approaches will only grow, allowing us to devise creative solutions that are both efficient and effective. Ultimately, embracing the concept of reduced scale can lead to more informed decision-making and a better future for our communities and the planet.

近年来，缩小比例的概念在建筑、城市规划和环境科学等多个领域引起了广泛关注。这个术语指的是以较小的尺寸创建大型系统的模型或表示的做法，这使得分析和理解复杂结构和过程变得更加容易。通过研究这些模型，研究人员和规划者可以识别潜在问题，并在不需要大量资源或耗时的全规模项目试验的情况下开发解决方案。在城市规划领域，缩小比例建模的一个显著应用是城市规划者常常利用缩小比例模型来可视化新开发项目如何融入现有环境。这种方法使他们能够评估建筑对交通流、绿地和社区动态的影响。例如，一个城市可能会创建一个缩小比例模型来评估拟建购物中心对当地商业和交通系统的影响。通过这样做，规划者可以做出明智的决策，促进可持续增长，提高居民的生活质量。此外，在建筑设计中，使用缩小比例模型使建筑师能够在投入全规模建设之前探索设计概念。这些模型作为可视化比例、材料和空间关系的宝贵工具。通过操纵建筑的缩小比例版本，建筑师可以尝试不同的配置和美学，确保最终产品满足功能和艺术目标。环境科学家也从缩小比例研究中受益，特别是在研究生态系统或自然现象时。通过创建栖息地的微型版本，研究人员可以在受控条件下观察物种与其环境之间的相互作用。这种方法提供了对生态动态的洞察，这在其自然全尺寸背景下将很难研究。例如，一个缩小比例的湿地模型可以帮助科学家理解水过滤过程以及污染物对生物多样性的影响。此外，缩小比例的概念不仅限于物理建模；它还适用于数据分析和模拟。在许多科学学科中，研究人员使用算法和计算模型来模拟现实世界场景，采用缩小比例的方法。这种方法允许对复杂系统（如气候变化或经济趋势）进行检查，而无需进行详尽的数据收集。通过分析这些模拟，科学家可以预测结果并制定减轻不良影响的策略。总之，缩小比例的理念在各个学科中都是一种强大的工具，使专业人士能够在各自领域内进行可视化、分析和创新。无论是在建筑和城市规划中的物理模型，还是在环境科学中的模拟，缩小比例方法都促进了对复杂系统的更深入理解。随着我们继续面临全球挑战，利用缩小比例方法的重要性只会增加，使我们能够制定既高效又有效的创造性解决方案。最终，拥抱缩小比例的概念将导致更明智的决策，为我们的社区和地球的未来带来更好的发展。