filling factor

简明释义

线圈间隙因数

英英释义

例句

1.A higher filling factor usually means better performance in electronic devices.

更高的填充因子通常意味着电子设备的性能更好。

2.The filling factor in this solar panel indicates its efficiency in converting sunlight into electricity.

这个太阳能电池板的填充因子表明其将阳光转化为电能的效率。

3.In our study, we measured the filling factor of various materials to determine their suitability for insulation.

在我们的研究中，我们测量了各种材料的填充因子以确定它们作为绝缘材料的适用性。

4.The filling factor of the circuit affects its overall power consumption.

电路的填充因子影响其整体功耗。

5.To improve the filling factor, engineers redesigned the layout of the components.

为了提高填充因子，工程师重新设计了组件的布局。

作文

In the realm of physics and engineering, the term filling factor refers to a crucial parameter that quantifies the efficiency of a given system. It is often used in various fields such as optics, electronics, and materials science to describe how effectively a certain area or volume is utilized by a particular substance or component. For instance, in the context of solar cells, the filling factor can indicate how much of the available sunlight is converted into usable electrical energy. A higher filling factor signifies better performance and efficiency, which is essential for optimizing energy output.Understanding the concept of filling factor is vital for engineers and scientists who aim to improve the functionality of their designs. In the case of photovoltaic cells, the filling factor is calculated by dividing the maximum power output of the cell by the product of its open-circuit voltage and short-circuit current. This ratio provides insights into the quality of the solar cell and its ability to convert sunlight into electricity. Therefore, researchers continuously strive to enhance the filling factor through innovative materials and design techniques.Moreover, the filling factor is not limited to solar technology. In the field of electronics, it plays a significant role in the design of integrated circuits. The filling factor determines how densely components can be packed within a chip without compromising performance. A higher filling factor in this context means more transistors can fit into a smaller area, leading to faster processing speeds and reduced power consumption. Engineers must balance the filling factor with thermal management and electrical interference to ensure reliable operation.In addition to its applications in technology, the filling factor also has implications in urban planning and architecture. For example, the filling factor of a building can refer to the ratio of usable space to the total area of the structure. Architects aim to maximize this ratio to create functional and efficient living spaces. By understanding how to manipulate the filling factor, they can design buildings that are not only aesthetically pleasing but also practical for everyday use.The significance of the filling factor extends beyond technical specifications; it embodies the principles of efficiency and optimization. Whether in renewable energy systems, electronic devices, or architectural designs, the filling factor serves as a guiding principle for innovation. As society continues to advance technologically, the quest for improved filling factor will drive research and development across multiple disciplines.In conclusion, the concept of filling factor is a multifaceted one that applies to various fields, each with its unique challenges and opportunities. By striving to enhance the filling factor, professionals can contribute to more sustainable, efficient, and effective solutions that meet the demands of an ever-evolving world. Understanding this term allows individuals to appreciate the complexities involved in design and optimization, paving the way for future advancements in technology and infrastructure.

在物理和工程领域，术语填充因子指的是一个关键参数，它量化了给定系统的效率。它通常用于光学、电子学和材料科学等多个领域，以描述某一特定区域或体积被特定物质或组件有效利用的程度。例如，在太阳能电池的背景下，填充因子可以指示可用阳光转化为可用电能的程度。较高的填充因子意味着更好的性能和效率，这对于优化能量输出至关重要。理解填充因子的概念对于希望提高其设计功能的工程师和科学家至关重要。在光伏电池的情况下，填充因子通过将电池的最大功率输出除以其开路电压和短路电流的乘积来计算。这个比率提供了关于太阳能电池质量及其将阳光转化为电力能力的见解。因此，研究人员不断努力通过创新材料和设计技术来提高填充因子。此外，填充因子不仅限于太阳能技术。在电子学领域，它在集成电路设计中也起着重要作用。填充因子决定了组件在芯片内可以多密集地打包，而不影响性能。在这种情况下，更高的填充因子意味着更多的晶体管可以适应更小的区域，从而提高处理速度并减少功耗。工程师必须在热管理和电干扰之间平衡填充因子，以确保可靠的操作。除了在技术中的应用外，填充因子在城市规划和建筑设计中也有影响。例如，建筑的填充因子可以指可用空间与结构总面积的比率。建筑师旨在最大化这一比率，以创建功能性和高效的生活空间。通过理解如何操控填充因子，他们可以设计出不仅美观而且实用的建筑。填充因子的重要性超越了技术规格；它体现了效率和优化的原则。无论是在可再生能源系统、电子设备还是建筑设计中，填充因子都作为创新的指导原则。随着社会继续在技术上进步，提高填充因子的追求将推动多个学科的研究和发展。总之，填充因子的概念是一个多面向的概念，适用于多个领域，每个领域都有其独特的挑战和机遇。通过努力提高填充因子，专业人士可以为满足不断发展的世界需求的更可持续、高效和有效的解决方案做出贡献。理解这个术语使个人能够欣赏设计和优化中涉及的复杂性，为未来在技术和基础设施方面的进步铺平道路。