distorted wave

简明释义

畸变波

英英释义

例句

1.When analyzing the signal, we noticed a distorted wave that affected the overall quality of the transmission.

在分析信号时，我们注意到一个失真波形，这影响了传输的整体质量。

2.During the live performance, a distorted wave was heard, causing concern among the sound crew.

在现场演出中，听到了一个失真波形，这让音响团队感到担忧。

3.The distorted wave pattern on the oscilloscope suggested interference from nearby electronic devices.

示波器上的失真波形模式表明附近电子设备的干扰。

4.To fix the issue, the technician had to eliminate the source of the distorted wave in the circuit.

为了解决这个问题，技术人员不得不消除电路中失真波形的源头。

5.The audio engineer identified a distorted wave in the recording, indicating a problem with the microphone.

音频工程师在录音中识别出了一个失真波形，这表明麦克风存在问题。

作文

In the realm of physics and engineering, the concept of a distorted wave plays a significant role in understanding various phenomena. A distorted wave refers to a wave that has been altered from its original form due to various factors such as interference, medium changes, or external influences. This alteration can manifest in different ways, including changes in amplitude, frequency, or waveform shape. Understanding distorted waves is crucial for applications ranging from telecommunications to medical imaging.To illustrate the importance of distorted waves, let's consider the field of telecommunications. When signals are transmitted over long distances, they can encounter various obstacles and mediums that distort their original waveform. For example, a radio signal may pass through buildings, trees, and other structures, leading to a distorted wave at the receiver's end. This distortion can result in poor sound quality or lost data, highlighting the need for engineers to develop methods for mitigating these distortions.Another area where distorted waves are relevant is in medical imaging technologies, such as ultrasound. In this context, sound waves are used to create images of the inside of the body. However, as these sound waves travel through different tissues, they can become distorted. Factors like density differences in tissues can cause the waves to change direction or speed, leading to inaccurate images. Medical professionals must account for these potential distorted waves when interpreting ultrasound results, ensuring that they provide accurate diagnoses.Furthermore, the study of distorted waves extends into the realm of music and audio engineering. Musicians and audio engineers often manipulate sound waves to create desired effects, resulting in a distorted wave that enhances the listening experience. For instance, electric guitarists frequently use distortion pedals to alter the sound waves produced by their instruments, creating a gritty and powerful tone that is characteristic of rock music. This intentional distortion showcases how distorted waves can be creatively utilized in art and entertainment.In addition to these practical applications, the theoretical study of distorted waves also contributes to our understanding of wave behavior in general. Scientists analyze how different types of distortions affect wave propagation, helping to refine existing models and develop new theories. For instance, researchers might explore how non-linear effects lead to the creation of shock waves, which are a specific type of distorted wave. By studying these phenomena, scientists can gain insights into complex systems across various fields, including meteorology, oceanography, and even astrophysics.In conclusion, the concept of a distorted wave is multifaceted and applicable in numerous fields, from telecommunications to medicine and music. Understanding how and why waves become distorted is essential for improving technologies and enhancing our comprehension of wave dynamics. As we continue to explore the intricacies of wave behavior, the significance of distorted waves will undoubtedly remain a vital area of study that bridges science, engineering, and art.

在物理和工程领域，扭曲波的概念在理解各种现象方面起着重要作用。扭曲波是指由于干扰、介质变化或外部影响等各种因素而改变了其原始形态的波。这种变化可以表现为幅度、频率或波形形状的变化。理解扭曲波对于从电信到医学成像等应用至关重要。为了说明扭曲波的重要性，让我们考虑电信领域。当信号在长距离上传输时，它们可能会遇到各种障碍和介质，从而扭曲其原始波形。例如，广播信号可能会穿过建筑物、树木和其他结构，导致接收端的扭曲波。这种失真可能导致音质差或数据丢失，这突显出工程师开发减轻这些失真的方法的必要性。扭曲波相关的另一个领域是在医学成像技术中，如超声。在这种情况下，声波用于创建身体内部的图像。然而，当这些声波穿过不同的组织时，它们可能会变得扭曲。组织密度的差异可能导致波的方向或速度发生变化，从而导致图像不准确。医学专业人员必须在解读超声结果时考虑这些潜在的扭曲波，以确保提供准确的诊断。此外，扭曲波的研究还扩展到音乐和音频工程领域。音乐家和音频工程师经常操纵声波以创造所需的效果，从而产生一种增强听觉体验的扭曲波。例如，电吉他手经常使用失真踏板来改变他们乐器产生的声波，创造出一种粗糙而强大的音调，这是摇滚音乐的特征。这种故意的失真展示了扭曲波在艺术和娱乐中的创造性利用。除了这些实际应用外，扭曲波的理论研究也有助于我们理解波动行为。科学家分析不同类型的失真如何影响波传播，帮助完善现有模型并开发新理论。例如，研究人员可能会探索非线性效应如何导致冲击波的产生，冲击波是一种特定类型的扭曲波。通过研究这些现象，科学家可以获得对气象学、海洋学甚至天体物理学等各个领域复杂系统的深入了解。总之，扭曲波的概念是多方面的，适用于从电信到医学和音乐等多个领域。理解波如何以及为何变得扭曲对于改善技术和增强我们对波动态的理解至关重要。随着我们继续探索波动行为的复杂性，扭曲波的重要性无疑将仍然是一个重要的研究领域，连接着科学、工程和艺术。