theoretical size

简明释义

理论尺寸

英英释义

例句

1.When designing the new smartphone, the team focused on the theoretical size of the battery for optimal performance.

在设计新智能手机时，团队专注于电池的理论尺寸以实现最佳性能。

2.The architect provided the theoretical size of the building in the proposal to facilitate planning.

建筑师在提案中提供了建筑的理论尺寸以便于规划。

3.In our physics experiment, we measured the theoretical size of the particles based on their mass and energy.

在我们的物理实验中，我们根据粒子的质量和能量测量了它们的理论尺寸。

4.The theoretical size of the molecule was determined using advanced computational models.

分子的理论尺寸是通过先进的计算模型确定的。

5.The engineer calculated the theoretical size of the bridge to ensure it could support the expected traffic load.

工程师计算了桥梁的理论尺寸以确保它能够支持预期的交通负荷。

作文

In the realm of science and engineering, the term theoretical size refers to a calculated or predicted dimension of an object based on mathematical models or formulas, rather than its actual physical measurement. This concept is crucial in various fields, including physics, materials science, and engineering design. Understanding theoretical size allows researchers and engineers to predict how materials will behave under certain conditions, which can lead to innovations and improvements in technology.For instance, when designing a new bridge, engineers often rely on the theoretical size of the materials being used to ensure that the structure will be safe and durable. They calculate the necessary dimensions and weight-bearing capacities based on theoretical principles of mechanics. This helps them determine whether the chosen materials will withstand the forces they will encounter in real-world conditions.Moreover, in the field of nanotechnology, the theoretical size plays a significant role in understanding how nanoparticles interact with their environment. Researchers study the theoretical size of these tiny particles to predict their behavior in biological systems, which is essential for developing drug delivery systems and other medical applications. The properties of materials can change drastically at the nanoscale, making it imperative to have accurate theoretical predictions.The importance of theoretical size extends beyond engineering and science; it also finds relevance in economics and social sciences. Economists may use theoretical size to model market behaviors, predicting how changes in one aspect of the economy might affect others. By using theoretical models, they can simulate various scenarios and make informed decisions about policy and investment.However, it is essential to recognize that theoretical size is not always synonymous with reality. Discrepancies often arise between theoretical predictions and actual measurements due to various factors such as environmental conditions, material imperfections, and human error. Therefore, while theoretical calculations provide a foundation for understanding and prediction, empirical testing remains a critical component of the scientific method.In conclusion, the concept of theoretical size is fundamental across multiple disciplines. It serves as a guiding principle for predictions and designs, enabling advancements in technology and knowledge. Nevertheless, it is vital to balance theoretical predictions with practical observations to achieve the most accurate understanding of the world around us. By doing so, we can harness the power of theoretical insights while remaining grounded in the realities of physical phenomena.

在科学和工程领域，术语理论尺寸指的是基于数学模型或公式计算或预测的物体尺寸，而不是其实际物理测量。这一概念在物理学、材料科学和工程设计等多个领域至关重要。理解理论尺寸使研究人员和工程师能够预测材料在特定条件下的表现，这可以促进技术的创新和改进。例如，在设计新桥时，工程师通常依赖所用材料的理论尺寸来确保结构的安全性和耐久性。他们根据力学的理论原则计算必要的尺寸和承重能力。这帮助他们确定所选材料是否能承受现实世界中遇到的力量。此外，在纳米技术领域，理论尺寸在理解纳米颗粒如何与环境相互作用方面发挥着重要作用。研究人员研究这些微小颗粒的理论尺寸以预测它们在生物系统中的行为，这对开发药物递送系统和其他医疗应用至关重要。在纳米尺度上，材料的性质可能会发生急剧变化，因此准确的理论预测是必不可少的。理论尺寸的重要性不仅限于工程和科学，它在经济学和社会科学中也有相关性。经济学家可能使用理论尺寸来模拟市场行为，预测经济中某一方面的变化将如何影响其他方面。通过使用理论模型，他们可以模拟各种情景，并就政策和投资做出明智的决策。然而，必须认识到，理论尺寸并不总是与现实同义。由于环境条件、材料缺陷和人为错误等各种因素，理论预测和实际测量之间常常会出现差异。因此，尽管理论计算为理解和预测提供了基础，但实证测试仍然是科学方法的关键组成部分。总之，理论尺寸的概念在多个学科中都是基础。它作为预测和设计的指导原则，使技术和知识得以进步。然而，将理论预测与实际观察相结合，以实现对我们周围世界的最准确理解，是至关重要的。通过这样做，我们可以利用理论洞察的力量，同时保持对物理现象现实的关注。