ohmic coupling

简明释义

电阻耦合

英英释义

例句

1.The researchers found that the efficiency of the device was significantly improved due to better ohmic coupling 欧姆耦合 between the semiconductor layers.

研究人员发现，由于半导体层之间的更好ohmic coupling 欧姆耦合，设备的效率显著提高。

2.The study highlighted the importance of ohmic coupling 欧姆耦合 in achieving high-performance electronic devices.

研究强调了在实现高性能电子设备中ohmic coupling 欧姆耦合的重要性。

3.In their experiments, they measured the temperature rise caused by ohmic coupling 欧姆耦合 in the circuit.

在他们的实验中，他们测量了电路中由于ohmic coupling 欧姆耦合引起的温度升高。

4.The design of the new battery incorporates ohmic coupling 欧姆耦合 to enhance power delivery.

新电池的设计采用ohmic coupling 欧姆耦合以增强电力传递。

5.By optimizing the ohmic coupling 欧姆耦合, the team was able to reduce energy losses in the system.

通过优化ohmic coupling 欧姆耦合，团队能够减少系统中的能量损失。

作文

In the realm of electrical engineering, the concept of ohmic coupling plays a pivotal role in understanding how different components interact with one another. Ohmic coupling refers to the electrical connection between two or more circuits or devices through which current flows in a manner that is governed by Ohm's law. This means that the relationship between voltage, current, and resistance is linear, making it easier for engineers to predict and control the behavior of electrical systems.When we delve deeper into the significance of ohmic coupling, it becomes clear that it is fundamental in various applications, ranging from simple circuits to complex electronic devices. For instance, consider a basic circuit consisting of a battery, a resistor, and a light bulb. The battery provides a voltage, which pushes the current through the resistor and the light bulb. The relationship between these components can be described using Ohm's law: V = IR, where V is the voltage, I is the current, and R is the resistance. In this scenario, the ohmic coupling between the battery, resistor, and light bulb ensures that the current flows smoothly, allowing the light bulb to illuminate.Moreover, ohmic coupling is not limited to passive components like resistors; it also applies to active components such as transistors and integrated circuits. In modern electronics, where miniaturization is key, understanding ohmic coupling is essential for designing circuits that are both efficient and reliable. Engineers must consider the resistance and capacitance of each component to ensure that the entire system operates as intended. Failure to account for ohmic coupling can lead to issues such as signal distortion, overheating, or even complete circuit failure.In addition to its practical applications, ohmic coupling also has theoretical implications in the field of physics. Researchers study the principles of ohmic coupling to gain insights into the behavior of materials at the microscopic level. For example, the conductivity of a material is influenced by its atomic structure and temperature. By examining how ohmic coupling affects current flow in different materials, scientists can develop new materials with tailored electrical properties, paving the way for advancements in technology.Furthermore, the importance of ohmic coupling extends to renewable energy systems, such as solar panels and wind turbines. These systems rely on efficient electrical connections to maximize energy conversion and minimize losses. Understanding ohmic coupling allows engineers to design better interfaces between energy sources and storage systems, ensuring that energy is harnessed effectively.In conclusion, ohmic coupling is a fundamental concept in electrical engineering and physics that underpins many aspects of modern technology. From simple circuits to complex electronic devices, the principles of ohmic coupling help engineers and scientists understand and control the flow of electricity. As technology continues to evolve, the relevance of ohmic coupling will only grow, highlighting the need for a deep understanding of this crucial concept in the pursuit of innovation and efficiency in electrical systems.

在电气工程领域，欧姆耦合的概念在理解不同组件如何相互作用方面发挥着关键作用。欧姆耦合是指两个或多个电路或设备之间的电连接，通过这种连接电流以受欧姆定律支配的方式流动。这意味着电压、电流和电阻之间的关系是线性的，使工程师能够更容易地预测和控制电气系统的行为。当我们深入探讨欧姆耦合的重要性时，显然它在各种应用中都是基础，从简单电路到复杂电子设备。例如，考虑一个由电池、电阻器和灯泡组成的基本电路。电池提供电压，推动电流通过电阻器和灯泡。组件之间的关系可以用欧姆定律来描述：V = IR，其中V是电压，I是电流，R是电阻。在这种情况下，欧姆耦合确保电池、电阻器和灯泡之间的电流流动顺畅，使灯泡发光。此外，欧姆耦合不仅限于被动组件，如电阻器；它也适用于诸如晶体管和集成电路等主动组件。在现代电子学中，微型化是关键，理解欧姆耦合对于设计高效且可靠的电路至关重要。工程师必须考虑每个组件的电阻和电容，以确保整个系统按预期运行。如果未能考虑欧姆耦合，可能会导致信号失真、过热甚至完全电路故障等问题。除了其实际应用外，欧姆耦合在物理学理论方面也具有重要意义。研究人员研究欧姆耦合的原理，以深入了解材料在微观水平上的行为。例如，材料的导电性受到其原子结构和温度的影响。通过检查欧姆耦合如何影响不同材料中的电流流动，科学家们可以开发具有定制电气特性的材料，为技术进步铺平道路。此外，欧姆耦合的重要性扩展到可再生能源系统，例如太阳能电池板和风力涡轮机。这些系统依赖高效的电连接，以最大限度地提高能量转换并减少损失。理解欧姆耦合使工程师能够设计更好的能量源与储存系统之间的接口，确保有效利用能量。总之，欧姆耦合是电气工程和物理学中的一个基本概念，它支撑着现代技术的许多方面。从简单电路到复杂电子设备，欧姆耦合的原理帮助工程师和科学家理解和控制电流的流动。随着技术的不断发展，欧姆耦合的相关性只会增加，突显出在追求电气系统创新和效率时深入理解这一关键概念的必要性。