differential excitation

简明释义

差励

英英释义

例句

1.The application of differential excitation 差分激发 in quantum systems has opened new avenues for research.

在量子系统中应用 differential excitation 差分激发 开辟了新的研究方向。

2.Researchers utilized differential excitation 差分激发 methods to isolate specific signals from background noise.

研究人员利用 differential excitation 差分激发 方法从背景噪声中隔离特定信号。

3.Using differential excitation 差分激发, scientists can enhance the detection of weak signals in a noisy environment.

利用 differential excitation 差分激发，科学家可以增强在嘈杂环境中微弱信号的检测。

4.The differential excitation 差分激发 technique improves the sensitivity of spectroscopic measurements.

该 differential excitation 差分激发 技术提高了光谱测量的灵敏度。

5.In advanced imaging techniques, differential excitation 差分激发 allows for better contrast in the resulting images.

在先进的成像技术中，differential excitation 差分激发 使得生成的图像具有更好的对比度。

作文

In the field of physics and engineering, the concept of differential excitation plays a crucial role in understanding how systems respond to varying stimuli. Essentially, differential excitation refers to the process by which different levels of energy or signals are applied to a system, resulting in varied responses. This principle is particularly significant in areas such as electrical engineering, where circuits may react differently based on the input they receive. For instance, consider a simple electronic circuit that includes resistors and capacitors. When a voltage is applied, the differential excitation of the components can lead to diverse outcomes in terms of current flow and signal output. If the voltage is increased incrementally, the system's response can be analyzed to determine how effectively it operates under different conditions. Understanding differential excitation allows engineers to design more efficient systems that can handle a range of inputs without failure.Moreover, differential excitation is not limited to electrical systems; it also extends to mechanical systems. In mechanical engineering, for example, the way a material responds to forces can be examined through differential excitation. By applying different loads to a material, engineers can ascertain its strength and durability, which is critical in construction and manufacturing processes. The insights gained from these experiments enable designers to select appropriate materials for specific applications, ensuring safety and efficacy.Furthermore, differential excitation is vital in control systems, where feedback mechanisms are employed to regulate performance. In such systems, the input signals can vary significantly, leading to different operational states. Engineers utilize the principles of differential excitation to fine-tune control algorithms, ensuring that the system remains stable and responsive under various conditions. This adaptability is essential in fields like robotics and automation, where precise control is necessary for successful operation.In addition to engineering applications, differential excitation also finds relevance in biological systems. For instance, neurons in the brain exhibit differential excitation when stimulated by various neurotransmitters. This differential response is fundamental to how information is processed and transmitted within the nervous system. Understanding the mechanisms behind differential excitation in biological contexts can lead to advancements in medical science, particularly in developing treatments for neurological disorders.In conclusion, the concept of differential excitation is pivotal across multiple disciplines, from engineering to biology. By examining how systems respond to varying levels of input, researchers and engineers can innovate and enhance performance in their respective fields. Whether optimizing circuit designs, improving material resilience, or unraveling the complexities of neural communication, differential excitation provides a framework for understanding and manipulating the behavior of complex systems. As technology continues to evolve, the importance of mastering differential excitation will only grow, highlighting the need for ongoing research and application in this fascinating area of study.

在物理和工程领域，differential excitation的概念在理解系统如何响应不同刺激方面发挥着至关重要的作用。基本上，differential excitation指的是将不同能量或信号水平施加到系统上，从而导致不同响应的过程。这个原理在电气工程等领域尤为重要，因为电路可能会根据接收到的输入而作出不同的反应。例如，考虑一个简单的电子电路，包括电阻器和电容器。当施加电压时，组件的differential excitation可以导致电流流动和信号输出的多样化结果。如果电压逐渐增加，可以分析系统的响应，以确定其在不同条件下的有效运行。理解differential excitation使工程师能够设计更高效的系统，以便在不失效的情况下处理一系列输入。此外，differential excitation不仅限于电气系统；它也扩展到机械系统。例如，在机械工程中，通过施加不同的载荷来检查材料对力的响应，可以通过differential excitation进行分析。通过对材料施加不同的负载，工程师可以确定其强度和耐久性，这在建筑和制造过程中至关重要。从这些实验中获得的见解使设计者能够选择适合特定应用的材料，确保安全性和有效性。此外，differential excitation在控制系统中也至关重要，其中使用反馈机制来调节性能。在这样的系统中，输入信号可能会显著变化，导致不同的操作状态。工程师利用differential excitation的原理来微调控制算法，确保系统在各种条件下保持稳定和响应。这种适应性在机器人技术和自动化等领域尤为重要，因为精确控制对于成功操作是必要的。除了工程应用，differential excitation在生物系统中也具有相关性。例如，大脑中的神经元在受到各种神经递质刺激时表现出differential excitation。这种差异响应对信息在神经系统中的处理和传递至关重要。理解生物背景下differential excitation背后的机制可以推动医学科学的发展，特别是在开发神经疾病治疗方面。总之，differential excitation的概念在多个学科中都是关键的，从工程到生物学。通过研究系统如何响应不同水平的输入，研究人员和工程师可以在各自的领域中进行创新和提升性能。无论是优化电路设计、提高材料韧性，还是解开神经通信的复杂性，differential excitation为理解和操控复杂系统的行为提供了框架。随着技术的不断发展，掌握differential excitation的重要性只会增加，突显出在这一迷人研究领域中持续研究和应用的必要性。