excitation source area

简明释义

激发源面积;

英英释义

例句

1.The design of the excitation source area was optimized for better performance in high-energy applications.

为了在高能应用中获得更好的性能，激发源区域的设计经过优化。

2.The researchers focused on the excitation source area to enhance the signal quality in their experiments.

研究人员专注于激发源区域以提高实验中的信号质量。

3.The excitation source area plays a crucial role in determining the output of the spectrometer.

在确定光谱仪的输出时，激发源区域起着至关重要的作用。

4.In our study, we measured the intensity of light emitted from the excitation source area.

在我们的研究中，我们测量了从激发源区域发出的光强度。

5.By adjusting the excitation source area, we were able to improve the efficiency of the laser system.

通过调整激发源区域，我们能够提高激光系统的效率。

作文

In the field of physics and engineering, the term excitation source area plays a crucial role in understanding how energy is transferred and utilized in various systems. The excitation source area refers to the specific region or zone where energy is introduced into a system, causing it to respond or react in a particular manner. This concept is especially significant in areas such as acoustics, optics, and electromagnetic theory, where the behavior of waves and particles is heavily influenced by the characteristics of the excitation source. To illustrate this, consider the example of a loudspeaker. The excitation source area in this case is the diaphragm of the speaker, which vibrates to create sound waves. When an electrical signal is applied to the speaker, the diaphragm moves back and forth, generating pressure waves in the air that we perceive as sound. The efficiency and quality of sound production are directly related to the properties of the excitation source area, including its size, material, and design. Similarly, in the realm of optics, lasers utilize a well-defined excitation source area to produce coherent light. The gain medium within a laser cavity acts as the excitation source area, where energy is pumped into the medium to excite the atoms or molecules. This excitation leads to the emission of photons, which are then amplified and emitted as a focused beam of light. The characteristics of the excitation source area determine the wavelength, intensity, and coherence of the emitted light, making it a critical factor in laser technology. Moreover, the concept of excitation source area extends beyond physical systems into biological contexts as well. For instance, in cellular biology, the excitation source area can refer to the specific sites on a cell membrane where signals are received, leading to cellular responses. These areas are crucial for processes such as signal transduction, where external stimuli are converted into cellular actions. Understanding the dynamics of the excitation source area in this context can provide insights into how cells communicate and respond to their environment, which has implications for fields such as medicine and biotechnology. In summary, the excitation source area is a fundamental concept that appears across various scientific disciplines. It represents the location where energy is introduced into a system, influencing the system's behavior and response. By studying and optimizing the excitation source area, researchers and engineers can enhance the performance of technologies ranging from audio systems to advanced optical devices. As we continue to explore and manipulate these excitation sources, we unlock new possibilities for innovation and discovery in science and technology.

在物理和工程领域，术语激发源区域在理解能量如何在各种系统中转移和利用方面起着至关重要的作用。激发源区域指的是将能量引入系统的特定区域或区域，从而导致其以特定方式响应或反应。这个概念在声学、光学和电磁理论等领域尤为重要，因为波和粒子的行为在很大程度上受到激发源特性的影响。为了说明这一点，考虑一下扬声器的例子。在这种情况下，激发源区域是扬声器的振膜，它通过振动产生声波。当电信号施加到扬声器时，振膜前后移动，在空气中产生压力波，我们将其感知为声音。声音产生的效率和质量与激发源区域的特性直接相关，包括其大小、材料和设计。同样，在光学领域，激光利用明确的激发源区域来产生相干光。激光腔内的增益介质充当激发源区域，在其中能量被泵送到介质中以激发原子或分子。这种激发导致光子的发射，然后被放大并作为聚焦光束发出。激发源区域的特性决定了发射光的波长、强度和相干性，使其成为激光技术中的关键因素。此外，激发源区域的概念不仅限于物理系统，还扩展到生物学背景。例如，在细胞生物学中，激发源区域可以指细胞膜上接收信号的特定位点，从而导致细胞反应。这些区域对于信号转导等过程至关重要，在这些过程中，外部刺激被转化为细胞行为。理解这一背景下激发源区域的动态可以提供有关细胞如何与环境交流和响应的见解，这对医学和生物技术等领域具有重要意义。总之，激发源区域是一个出现在各种科学学科中的基本概念。它代表了能量引入系统的位置，影响系统的行为和反应。通过研究和优化激发源区域，研究人员和工程师可以增强从音频系统到先进光学设备的技术性能。随着我们继续探索和操纵这些激发源，我们为科学和技术的创新与发现开辟了新的可能性。