mutual conductance

简明释义

互导

英英释义

例句

1.The circuit's performance improved significantly after we measured the mutual conductance 互导电导 between the two components.

在我们测量了两个组件之间的mutual conductance 互导电导后，电路的性能显著提高。

2.To optimize the system, we need to calculate the mutual conductance 互导电导 of the interconnected circuits.

为了优化系统，我们需要计算互连电路的mutual conductance 互导电导。

3.In this experiment, we are analyzing the mutual conductance 互导电导 to understand how the two materials interact.

在这个实验中，我们正在分析mutual conductance 互导电导以了解这两种材料如何相互作用。

4.The researchers found a correlation between temperature changes and mutual conductance 互导电导 in their semiconductor samples.

研究人员发现温度变化与他们的半导体样品中的mutual conductance 互导电导之间存在相关性。

5.The software can simulate the mutual conductance 互导电导 between various electronic components for better design.

该软件可以模拟各种电子组件之间的mutual conductance 互导电导以便更好地设计。

作文

In the realm of electrical engineering and physics, the concept of mutual conductance plays a crucial role in understanding the behavior of circuits and systems. Mutual conductance refers to the measure of how well one component can influence the current flow through another component when both are connected within a circuit. This phenomenon is particularly important in the analysis of multi-port networks, where multiple inputs and outputs are present. The significance of mutual conductance can be illustrated through its applications in various electronic devices and systems.For instance, in the field of telecommunications, components such as amplifiers and filters rely heavily on the principles of mutual conductance to function effectively. In an amplifier circuit, the input signal can affect the output signal, and the degree to which this occurs is determined by the mutual conductance between the input and output stages. A high mutual conductance indicates that a small change in the input will result in a significant change in the output, thus enhancing the performance of the amplifier.Moreover, mutual conductance is not limited to linear systems; it also plays a vital role in nonlinear systems, where the relationship between voltage and current is not directly proportional. In such cases, understanding mutual conductance becomes essential for predicting how changes in one part of the system can affect others. This is especially true in complex systems like integrated circuits, where numerous components interact with each other simultaneously.The mathematical representation of mutual conductance is often expressed in terms of parameters that describe the relationship between voltages and currents in different parts of a network. Engineers and scientists utilize these parameters to design circuits that optimize performance based on desired specifications. For example, in a two-port network, the mutual conductance can be represented by the transconductance parameter, which quantifies the efficiency of current transfer from one port to another. Understanding mutual conductance also aids in the design of sensors and actuators, where the interaction between different elements must be finely tuned for optimal performance. In sensor applications, the mutual conductance between a sensing element and its environment can determine the sensitivity and responsiveness of the sensor. Similarly, in actuators, the mutual conductance affects how effectively an actuator can respond to control signals.In conclusion, the concept of mutual conductance is fundamental in the study and application of electrical circuits and systems. Its relevance spans across various fields, including telecommunications, sensor technology, and integrated circuit design. By comprehending mutual conductance, engineers and scientists can create more efficient and effective devices that meet the demands of modern technology. As we continue to advance in the field of electronics, the importance of understanding mutual conductance will only grow, leading to innovations that enhance our daily lives and drive technological progress.

在电气工程和物理学领域，互导的概念在理解电路和系统的行为中发挥着至关重要的作用。互导是指当两个组件连接在电路中时，一个组件对另一个组件的电流流动的影响程度。这种现象在多端口网络的分析中尤为重要，因为该网络存在多个输入和输出。互导的重要性可以通过其在各种电子设备和系统中的应用来说明。例如，在电信领域，放大器和滤波器等组件在功能上严重依赖于互导的原理。在放大器电路中，输入信号可以影响输出信号，而这种影响的程度由输入和输出阶段之间的互导决定。高互导表示输入的小变化将导致输出的显著变化，从而提高放大器的性能。此外，互导不仅限于线性系统；它在非线性系统中也起着至关重要的作用，在这些系统中，电压和电流之间的关系不是直接成比例的。在这种情况下，理解互导对于预测系统中一个部分的变化如何影响其他部分变得至关重要。这在集成电路等复杂系统中尤其如此，这些系统中众多组件同时相互作用。互导的数学表示通常用描述网络中不同部分电压和电流关系的参数来表达。工程师和科学家利用这些参数设计电路，以根据所需规格优化性能。例如，在两端口网络中，互导可以通过跨导参数表示，该参数量化了从一个端口到另一个端口的电流传输效率。理解互导还有助于传感器和执行器的设计，其中不同元素之间的相互作用必须精细调节以实现最佳性能。在传感器应用中，传感元件与其环境之间的互导可以决定传感器的灵敏度和响应能力。同样，在执行器中，互导影响执行器对控制信号的响应效果。总之，互导的概念在电路和系统的研究和应用中是基础性的。其相关性跨越多个领域，包括电信、传感器技术和集成电路设计。通过理解互导，工程师和科学家可以创建更高效、更有效的设备，以满足现代技术的需求。随着我们在电子领域的不断进步，理解互导的重要性只会增加，从而推动增强我们日常生活的创新和技术进步。