radiation interference

简明释义

辐射干扰

英英释义

例句

1.Engineers must consider radiation interference when designing sensitive electronic equipment.

工程师在设计敏感电子设备时必须考虑辐射干扰。

2.The research focused on mitigating radiation interference in communication systems.

该研究专注于减轻通信系统中的辐射干扰。

3.Scientists are studying the effects of radiation interference on GPS signals.

科学家正在研究辐射干扰对GPS信号的影响。

4.During the solar storm, many devices experienced radiation interference that disrupted their functions.

在太阳风暴期间，许多设备经历了辐射干扰，导致其功能受阻。

5.The satellite's signal was affected by radiation interference, causing a temporary loss of communication.

卫星信号受到辐射干扰的影响，导致通信暂时中断。

作文

In today's technologically advanced world, we rely heavily on various forms of communication and data transmission. However, one of the significant challenges we face in this digital age is the phenomenon known as radiation interference. This term refers to the disruption of signals caused by electromagnetic radiation emitted from various sources, which can lead to a degradation of the quality of communication and data transfer. Understanding radiation interference is crucial for both individuals and industries that depend on electronic devices and wireless communication. To comprehend the impact of radiation interference, it is essential to recognize the sources of electromagnetic radiation. Common sources include mobile phones, Wi-Fi routers, microwaves, and even natural phenomena like lightning. When these devices emit radiation, they can interfere with the signals transmitted by other devices, leading to issues such as dropped calls, slow internet speeds, and poor audio or video quality during streaming. The effects of radiation interference are not limited to personal inconveniences; they can also pose significant challenges for businesses and critical infrastructure. For instance, hospitals rely on precise communication between medical devices to ensure patient safety. Any disruption caused by radiation interference can have dire consequences, potentially endangering lives. Similarly, industries such as aviation and telecommunications invest heavily in technologies to mitigate the effects of radiation interference, ensuring that their operations remain efficient and reliable. Moreover, as the number of electronic devices continues to grow exponentially, the potential for radiation interference increases. The Internet of Things (IoT), which connects everyday objects to the internet, has added another layer of complexity to this issue. With more devices communicating wirelessly, the likelihood of interference rises, making it imperative for engineers and developers to design systems that can withstand or minimize the effects of radiation interference. To address the challenges posed by radiation interference, several strategies can be implemented. One approach is to enhance the shielding of devices, which involves using materials that can block or absorb electromagnetic radiation. This method can significantly reduce the impact of interference on sensitive equipment. Additionally, frequency management plays a vital role; by allocating specific frequencies for different types of devices, we can minimize overlap and reduce the chances of interference. Furthermore, advancements in technology, such as the development of more robust error correction algorithms, can help improve the resilience of communication systems against radiation interference. These algorithms can detect and correct errors caused by interference, ensuring that the integrity of the transmitted data remains intact. In conclusion, radiation interference is a critical issue that affects our increasingly connected world. As we continue to innovate and expand our reliance on electronic communication, understanding and addressing the challenges of radiation interference will be vital. By implementing effective strategies and leveraging technological advancements, we can mitigate the effects of interference, ensuring that our devices communicate seamlessly and efficiently. Ultimately, recognizing the significance of radiation interference will empower us to create a more reliable and interconnected future.

在当今技术先进的世界中，我们在很大程度上依赖于各种形式的通信和数据传输。然而，在这个数字时代，我们面临的一个重大挑战是被称为辐射干扰的现象。这个术语指的是由各种来源发出的电磁辐射造成的信号中断，这可能导致通信和数据传输质量的下降。理解辐射干扰对依赖电子设备和无线通信的个人和行业至关重要。要理解辐射干扰的影响，首先必须认识到电磁辐射的来源。常见的来源包括手机、Wi-Fi路由器、微波炉，甚至自然现象如闪电。当这些设备发出辐射时，它们可能会干扰其他设备传输的信号，导致掉线、互联网速度缓慢，以及在流媒体播放过程中音频或视频质量差等问题。辐射干扰的影响不仅限于个人的不便；它们还可能对企业和关键基础设施构成重大挑战。例如，医院依赖医疗设备之间的精确通信来确保患者安全。任何由辐射干扰造成的中断都可能产生严重后果，潜在地危及生命。同样，航空和电信等行业在减轻辐射干扰影响方面投入大量资金，以确保其运营保持高效可靠。此外，随着电子设备数量的不断激增，辐射干扰的潜力也在增加。物联网（IoT）将日常物品连接到互联网，为这一问题增加了另一个复杂层面。随着越来越多的设备无线通信，干扰的可能性上升，这使得工程师和开发人员必须设计能够承受或最小化辐射干扰影响的系统。为了解决辐射干扰带来的挑战，可以实施几种策略。一种方法是增强设备的屏蔽，这涉及使用能够阻挡或吸收电磁辐射的材料。这种方法可以显著减少干扰对敏感设备的影响。此外，频率管理也起着至关重要的作用；通过为不同类型的设备分配特定频率，我们可以最小化重叠，从而减少干扰的机会。此外，技术进步，例如更强大的错误校正算法的发展，可以帮助提高通信系统对辐射干扰的抗干扰能力。这些算法可以检测并纠正由于干扰而导致的错误，确保传输数据的完整性保持不变。总之，辐射干扰是一个影响我们日益互联世界的重要问题。随着我们继续创新并扩大对电子通信的依赖，理解和应对辐射干扰的挑战将至关重要。通过实施有效的策略和利用技术进步，我们可以减轻干扰的影响，确保我们的设备无缝高效地通信。最终，认识到辐射干扰的重要性将使我们能够创造一个更可靠、更互联的未来。