distorted wave

简明释义

畸变波

英英释义

例句

1.The audio engineer noticed a distorted wave in the recording, indicating a problem with the microphone.

音频工程师注意到录音中有一个失真波形，这表明麦克风存在问题。

2.In the simulation, we analyzed how a distorted wave affects the overall signal integrity.

在模拟中，我们分析了失真波形如何影响整体信号完整性。

3.When the frequency is too high, the output can create a distorted wave, leading to unwanted noise.

当频率过高时，输出可能会产生失真波形，导致不必要的噪音。

4.The speaker's voice had a distorted wave pattern due to the poor acoustics of the room.

由于房间的声学效果差，演讲者的声音呈现出失真波形模式。

5.The distorted wave from the guitar amplifier was a signature sound for the band's music.

吉他放大器发出的失真波形是乐队音乐的标志性声音。

作文

In the realm of physics and engineering, waves are fundamental phenomena that describe the propagation of energy through various mediums. Among these waves, the concept of a distorted wave plays a crucial role in understanding how energy can be affected by different factors. A distorted wave refers to a wave that has been altered from its original form due to various influences such as obstacles, interactions with other waves, or changes in the medium itself. This alteration can lead to significant changes in the wave's characteristics, including its amplitude, frequency, and phase. To illustrate the concept of a distorted wave, consider the example of sound waves traveling through air. When a sound wave is produced, it propagates in a regular pattern, creating a smooth and continuous wave. However, if this sound wave encounters an object, such as a wall or a piece of furniture, it may reflect, refract, or diffract. These interactions can cause the original sound wave to become distorted, leading to echoes, muffled sounds, or even new frequencies being generated. The resulting distorted wave may have different properties compared to the original wave, affecting how we perceive the sound.In addition to sound waves, distorted waves are also prevalent in the field of optics. Light waves, like sound waves, can also be distorted when they pass through various materials or encounter obstacles. For instance, when light passes through a prism, it bends and separates into different colors, creating a spectrum. This bending of light is a form of distortion that alters the wave's path and can lead to fascinating visual effects. Similarly, when light waves are obstructed by objects, they can create shadows or patterns that differ from the original light source. Understanding these distorted waves is essential for applications in photography, telecommunications, and even astronomy.Moreover, distorted waves can have practical implications in technology and communication. In signal processing, engineers often deal with distorted waves when transmitting information over long distances. For instance, radio waves can become distorted due to interference from buildings, trees, or atmospheric conditions. This distortion can affect the quality of the received signal, making it challenging to decode the information accurately. Engineers employ various techniques to mitigate these distortions, ensuring that the transmitted signals maintain their integrity and clarity.In conclusion, the concept of a distorted wave is vital in various scientific and technological contexts. Whether in sound, light, or electromagnetic waves, understanding how waves can be distorted helps us comprehend the complexities of wave behavior and its implications in real-world applications. As we continue to explore the intricacies of waves, the study of distorted waves will undoubtedly remain a key area of interest and research, leading to advancements in multiple fields such as acoustics, optics, and communications. By appreciating the significance of distorted waves, we can gain deeper insights into the nature of waves and their impact on our daily lives.

在物理和工程领域，波是描述能量通过各种介质传播的基本现象。在这些波中，扭曲波的概念在理解能量如何受到不同因素影响方面发挥着至关重要的作用。扭曲波指的是由于障碍物、与其他波的相互作用或介质本身的变化等各种影响而改变其原始形态的波。这种改变可能导致波的特性发生显著变化，包括其振幅、频率和相位。为了说明扭曲波的概念，考虑声音波通过空气传播的例子。当产生声波时，它以规则的方式传播，形成平滑且连续的波。然而，如果这声波遇到物体，例如墙壁或家具，它可能会反射、折射或衍射。这些相互作用可能导致原始声波变得扭曲，从而产生回声、模糊的声音，甚至生成新的频率。最终结果是，扭曲波的特性可能与原始波有所不同，影响我们对声音的感知。除了声波，扭曲波在光学领域也很常见。光波，像声波一样，当它们通过各种材料或遇到障碍物时，也会发生扭曲。例如，当光线通过棱镜时，它会弯曲并分离成不同的颜色，形成光谱。这种光的弯曲是一种扭曲形式，它改变了波的路径，并可能导致迷人的视觉效果。类似地，当光波被物体遮挡时，它们可以产生阴影或图案，与原始光源不同。理解这些扭曲波对于摄影、电信，甚至天文学等应用至关重要。此外，扭曲波在技术和通信中的实际意义也很大。在信号处理领域，工程师在长距离传输信息时经常处理扭曲波。例如，无线电波由于建筑物、树木或气候条件的干扰而可能变得扭曲。这种扭曲可能影响接收信号的质量，使得准确解码信息变得具有挑战性。工程师采用各种技术来减轻这些扭曲，确保传输信号保持其完整性和清晰度。总之，扭曲波的概念在各种科学和技术背景中至关重要。无论是在声音、光还是电磁波中，理解波如何被扭曲有助于我们理解波行为的复杂性及其在现实世界应用中的影响。随着我们继续探索波的复杂性，扭曲波的研究无疑将仍然是一个关键的兴趣和研究领域，推动声学、光学和通信等多个领域的进步。通过欣赏扭曲波的重要性，我们可以更深入地了解波的性质及其对我们日常生活的影响。