extraneous waves

简明释义

寄生波

英英释义

例句

1.To achieve accurate measurements, it is essential to account for extraneous waves in the environment.

为了获得准确的测量结果，考虑环境中的多余波动是必不可少的。

2.During the experiment, we encountered several extraneous waves that complicated our results.

在实验过程中，我们遇到了几种多余波动，这使我们的结果变得复杂。

3.The signal processing algorithm was designed to minimize the effect of extraneous waves.

该信号处理算法旨在最小化多余波动的影响。

4.In audio engineering, it's crucial to eliminate extraneous waves that can distort sound quality.

在音频工程中，消除可能扭曲音质的多余波动至关重要。

5.The researchers filtered out the extraneous waves to improve the clarity of their data.

研究人员过滤掉了多余波动以提高数据的清晰度。

作文

In the world of physics and engineering, waves play a crucial role in various applications, from telecommunications to medical imaging. However, not all waves are beneficial; some can interfere with the desired signals we aim to capture or transmit. One such phenomenon is the presence of extraneous waves, which refers to unwanted or irrelevant waveforms that can distort or obscure the primary signal. Understanding extraneous waves is essential for engineers and scientists to enhance the clarity and accuracy of their work.To illustrate the impact of extraneous waves, consider the field of telecommunications. When transmitting data over long distances, signals can become weakened due to various factors, including environmental conditions and equipment limitations. In many cases, extraneous waves generated by nearby electronic devices or natural phenomena, such as lightning, can introduce noise into the communication channel. This noise can lead to data loss or misinterpretation, ultimately affecting the quality of service provided to users.Another area where extraneous waves pose a significant challenge is in medical imaging technologies, such as ultrasound and MRI. For instance, during an ultrasound examination, the machine emits sound waves that bounce off internal organs to create images. However, if extraneous waves are present, they can produce artifacts in the images, making it difficult for healthcare professionals to diagnose conditions accurately. Therefore, minimizing extraneous waves is vital for ensuring that medical images are clear and reliable.Moreover, the concept of extraneous waves extends beyond the physical realm into areas like music and audio production. In music recording, extraneous sounds, such as background noise or interference from other instruments, can detract from the quality of the final product. Sound engineers often employ various techniques to filter out extraneous waves and focus on the desired audio, ensuring that the listener experiences the music as intended.The importance of identifying and managing extraneous waves cannot be overstated. In scientific research, the presence of these unwanted waves can skew results, leading to incorrect conclusions. Researchers must develop methods to isolate their signals from extraneous waves to ensure the integrity of their findings. This often involves using advanced filtering techniques and signal processing algorithms to distinguish between the relevant data and the noise.In conclusion, extraneous waves represent a significant hurdle across various fields, from telecommunications to medical imaging and audio production. By recognizing the sources and effects of these unwanted waveforms, professionals can implement strategies to mitigate their impact. As technology continues to advance, the ability to effectively manage extraneous waves will be crucial in enhancing the performance and reliability of systems that rely on wave transmission and reception. Ultimately, understanding and controlling extraneous waves is key to achieving clarity and precision in both scientific and practical applications.

在物理和工程的世界中，波在各种应用中发挥着至关重要的作用，从电信到医学成像。然而，并非所有的波都是有益的；一些波可能会干扰我们旨在捕获或传输的信号。一个这样的现象是存在多余波，指的是不必要或无关的波形，可能会扭曲或模糊主要信号。理解多余波对工程师和科学家来说至关重要，以增强他们工作的清晰度和准确性。为了说明多余波的影响，考虑电信领域。当数据在长距离上传输时，由于环境条件和设备限制等各种因素，信号可能会减弱。在许多情况下，由附近电子设备或自然现象（如闪电）产生的多余波可能会在通信通道中引入噪声。这种噪声可能导致数据丢失或误解，最终影响提供给用户的服务质量。另一个多余波带来重大挑战的领域是医学成像技术，如超声波和磁共振成像（MRI）。例如，在超声检查过程中，机器发出声波，这些声波反射内部器官以创建图像。然而，如果存在多余波，它们可能会在图像中产生伪影，使医疗专业人员难以准确诊断病症。因此，最小化多余波对于确保医学图像清晰可靠至关重要。此外，多余波的概念不仅限于物理领域，还扩展到音乐和音频制作等领域。在音乐录制中，背景噪声或其他乐器的干扰等多余声音可能会削弱最终产品的质量。声音工程师通常采用各种技术来过滤掉多余波，专注于所需的音频，确保听众体验到音乐的本意。识别和管理多余波的重要性不容小觑。在科学研究中，这些不必要的波的存在可能会扭曲结果，导致错误的结论。研究人员必须开发方法来将他们的信号与多余波隔离，以确保他们发现的完整性。这通常涉及使用先进的过滤技术和信号处理算法来区分相关数据和噪声。总之，多余波在各个领域中代表着一个重大障碍，从电信到医学成像和音频制作。通过识别这些不必要波形的来源和影响，专业人员可以实施策略以减轻其影响。随着技术的不断进步，有效管理多余波的能力对于提高依赖波传输和接收的系统的性能和可靠性至关重要。最终，理解和控制多余波是实现科学和实际应用中清晰度和精确性的关键。