magnetic interfering field

简明释义

干扰磁场

英英释义

例句

1.To achieve accurate measurements, the laboratory must be free from any magnetic interfering field.

为了获得准确的测量，实验室必须没有任何磁干扰场。

2.Researchers are investigating how the magnetic interfering field affects MRI imaging quality.

研究人员正在调查磁干扰场如何影响MRI成像质量。

3.In telecommunications, it's crucial to minimize the magnetic interfering field to ensure clear signal transmission.

在电信中，减少磁干扰场至关重要，以确保信号传输清晰。

4.The scientist measured the effects of the magnetic interfering field on the electronic devices in the lab.

科学家测量了实验室中电子设备受到的磁干扰场的影响。

5.The new design of the sensor aims to reduce the impact of the magnetic interfering field during operation.

传感器的新设计旨在减少操作过程中磁干扰场的影响。

作文

In the realm of physics and engineering, the concept of a magnetic interfering field plays a crucial role in understanding how magnetic fields can affect various systems. A magnetic interfering field is essentially an unwanted magnetic field that disrupts the operation of electronic devices, sensors, and other equipment that rely on precise magnetic measurements. This phenomenon can lead to inaccuracies and malfunctions, making it a significant concern in many applications, from telecommunications to medical imaging.To comprehend the implications of a magnetic interfering field, one must first grasp the fundamentals of magnetism. Magnetism is a force that arises from the motion of electric charges, and it manifests in various forms, such as permanent magnets and electromagnets. When these magnetic fields interact with materials or devices that are sensitive to magnetic changes, they can create interference, leading to erroneous readings or operational failures.For instance, in the field of medical imaging, technologies like Magnetic Resonance Imaging (MRI) rely heavily on stable magnetic fields to produce accurate images of the human body. However, the presence of a magnetic interfering field can distort the magnetic resonance signals, resulting in poor image quality or misdiagnosis. Therefore, it is imperative to minimize such interference through careful design and shielding techniques.Moreover, in telecommunications, where signals are transmitted via electromagnetic waves, a magnetic interfering field can disrupt communication channels. This interference can manifest as noise, leading to dropped calls or unclear audio. Engineers must consider potential sources of interference when designing communication systems, ensuring that they can operate effectively in environments where magnetic interfering fields may be present.The impact of a magnetic interfering field extends beyond just technological applications; it also has implications for scientific research. In experimental physics, researchers often work with highly sensitive instruments that measure minute magnetic fields. The presence of an unintended magnetic interfering field can skew results, making it challenging to draw accurate conclusions from experiments. Thus, scientists must implement rigorous control measures to isolate their instruments from external magnetic influences.In response to the challenges posed by magnetic interfering fields, various strategies have been developed. One common approach is the use of magnetic shielding materials that can absorb or redirect magnetic fields, thereby protecting sensitive equipment from interference. Additionally, advancements in technology have led to the development of more sophisticated algorithms and filtering techniques that can help mitigate the effects of interference in data processing.In conclusion, the phenomenon of a magnetic interfering field is a critical consideration across multiple disciplines, including engineering, medicine, and scientific research. Understanding its implications allows professionals to design better systems, improve accuracy, and enhance the reliability of various technologies. As we continue to advance in our understanding of magnetism and its applications, addressing the challenges posed by magnetic interfering fields will remain a vital area of focus for researchers and engineers alike. By prioritizing this aspect, we can ensure the continued progress of technology and its benefits to society as a whole.

在物理和工程领域，磁干扰场的概念在理解磁场如何影响各种系统方面发挥着至关重要的作用。磁干扰场本质上是指一种不必要的磁场，它干扰电子设备、传感器和其他依赖精确磁测量的设备的操作。这种现象可能导致不准确和故障，因此在许多应用中都是一个重要问题，从电信到医学成像。为了理解磁干扰场的影响，首先必须掌握磁性基础知识。磁性是一种由电荷运动产生的力，表现为各种形式，如永久磁铁和电磁铁。当这些磁场与对磁变化敏感的材料或设备相互作用时，会造成干扰，导致错误的读数或操作失败。例如，在医学成像领域，像磁共振成像（MRI）这样的技术在产生人体准确图像时严重依赖稳定的磁场。然而，磁干扰场的存在可能会扭曲磁共振信号，导致图像质量差或误诊。因此，必须通过仔细的设计和屏蔽技术来最小化这种干扰。此外，在电信领域，信号通过电磁波传输，磁干扰场可能会干扰通信通道。这种干扰可能表现为噪声，导致通话中断或音频不清晰。工程师在设计通信系统时必须考虑潜在的干扰源，确保它们能够在可能存在磁干扰场的环境中有效运行。磁干扰场的影响不仅限于技术应用；它还对科学研究产生影响。在实验物理学中，研究人员经常使用高度敏感的仪器来测量微小的磁场。意外的磁干扰场的存在可能会扭曲结果，使得从实验中得出准确结论变得困难。因此，科学家必须实施严格的控制措施，以将其仪器与外部磁场影响隔离。为了应对磁干扰场带来的挑战，已经开发出多种策略。一种常见的方法是使用能够吸收或引导磁场的磁屏蔽材料，从而保护敏感设备免受干扰。此外，技术的进步还导致了更复杂的算法和过滤技术的发展，这些技术可以帮助减轻数据处理中的干扰影响。总之，磁干扰场现象是多个学科中的关键考虑因素，包括工程、医学和科学研究。理解其影响使专业人士能够设计更好的系统，提高准确性，并增强各种技术的可靠性。随着我们在磁性及其应用方面的理解不断深入，解决磁干扰场所带来的挑战仍将是研究人员和工程师关注的重要领域。通过优先考虑这一方面，我们可以确保技术的持续进步及其对社会整体的益处。