atmospheric interference

简明释义

大气噪声

英英释义

例句

1.During the storm, we experienced significant atmospheric interference that affected our communication systems.

在风暴期间，我们经历了显著的大气干扰，这影响了我们的通信系统。

2.Astronomers must account for atmospheric interference when observing distant celestial bodies.

天文学家在观察遥远的天体时必须考虑大气干扰。

3.The pilot reported atmospheric interference affecting the radar systems during the flight.

飞行员报告称，飞行过程中雷达系统受到大气干扰的影响。

4.The satellite's signal was disrupted due to atmospheric interference.

由于大气干扰，卫星信号受到干扰。

5.The scientists measured atmospheric interference to improve the accuracy of their weather forecasts.

科学家们测量了大气干扰以提高天气预报的准确性。

作文

In our modern world, we rely heavily on technology for communication, navigation, and data transmission. However, one of the significant challenges that affect these technologies is atmospheric interference. This term refers to the disturbances in signals caused by various atmospheric conditions, which can significantly impact the quality and reliability of communications. Understanding atmospheric interference is essential for improving our technological frameworks and ensuring seamless connectivity.First, let's explore what causes atmospheric interference. The Earth's atmosphere is composed of various layers filled with different gases and particles. When signals, such as radio waves or satellite transmissions, travel through these layers, they can encounter obstacles that distort or weaken them. Factors like humidity, temperature fluctuations, and even solar activity can contribute to this interference. For instance, during heavy rainfall, the water droplets can absorb and scatter radio waves, leading to degraded signal quality. Similarly, solar flares can produce bursts of radiation that disrupt satellite communications, showcasing the vulnerability of our technology to natural phenomena.The effects of atmospheric interference are far-reaching. In aviation, pilots rely on precise navigation systems that can be compromised by interference. A minor disruption can lead to miscalculations in flight paths, potentially putting lives at risk. In telecommunications, users may experience dropped calls or poor internet connectivity due to atmospheric interference, leading to frustration and inefficiency. In scientific research, accurate data collection can be hindered by these atmospheric disturbances, affecting everything from climate studies to astronomical observations.To mitigate the impacts of atmospheric interference, researchers and engineers are continuously developing advanced technologies. One approach is to enhance signal processing techniques that can filter out noise caused by atmospheric conditions. For example, adaptive filtering algorithms can dynamically adjust to changing conditions, helping to maintain the integrity of transmitted signals. Additionally, the deployment of more robust satellite systems equipped with better shielding against radiation can reduce the effects of solar activity on communications.Moreover, understanding atmospheric interference allows for better planning and preparation. For instance, during periods of increased solar activity, organizations can anticipate potential disruptions and take proactive measures to ensure continuity of service. Weather forecasting can also play a role; by predicting adverse weather conditions, telecom companies can prepare their infrastructure to minimize the impact of atmospheric interference on their networks.In conclusion, while atmospheric interference presents challenges to our technological advancements, it also drives innovation and improvement in communication systems. By acknowledging the factors that contribute to this interference and investing in solutions, we can enhance the resilience of our technologies. As we continue to advance into an increasingly connected world, understanding and addressing atmospheric interference will be crucial for ensuring reliable and efficient communication across all sectors of society.

在我们现代世界中，我们在通信、导航和数据传输方面高度依赖技术。然而，影响这些技术的一个重大挑战是大气干扰。这个术语指的是由各种大气条件引起的信号干扰，这可能显著影响通信的质量和可靠性。理解大气干扰对于改善我们的技术框架和确保无缝连接至关重要。首先，让我们探讨一下是什么导致了大气干扰。地球的大气由不同层次的气体和颗粒组成。当信号，如无线电波或卫星传输，通过这些层传播时，它们可能会遇到障碍，从而扭曲或削弱信号。湿度、温度波动甚至太阳活动等因素都可能导致这种干扰。例如，在大雨期间，水滴可以吸收和散射无线电波，导致信号质量降低。同样，太阳耀斑可以产生辐射爆发，干扰卫星通信，展示了我们的技术对自然现象的脆弱性。大气干扰的影响是深远的。在航空领域，飞行员依赖精确的导航系统，而这些系统可能因干扰而受到影响。轻微的干扰可能导致航线计算错误，潜在地危及生命。在电信领域，用户可能会因大气干扰而经历掉话或互联网连接不良，导致沮丧和低效。在科学研究中，准确的数据收集可能因这些大气干扰而受到阻碍，影响从气候研究到天文学观察的方方面面。为了减轻大气干扰的影响，研究人员和工程师们不断开发先进的技术。一种方法是增强信号处理技术，以过滤掉由大气条件引起的噪声。例如，自适应滤波算法可以动态调整以适应变化的条件，帮助保持传输信号的完整性。此外，部署更强大的卫星系统，配备更好的辐射屏蔽，可以减少太阳活动对通信的影响。此外，理解大气干扰可以更好地进行规划和准备。例如，在太阳活动增加的时期，组织可以预见潜在的干扰，并采取主动措施以确保服务的连续性。天气预报也可以发挥作用；通过预测不利天气条件，电信公司可以准备其基础设施，以最小化大气干扰对其网络的影响。总之，虽然大气干扰给我们的技术进步带来了挑战，但它也推动了通信系统的创新和改进。通过承认导致这种干扰的因素并投资于解决方案，我们可以增强我们技术的韧性。随着我们继续迈向一个日益互联的世界，理解和解决大气干扰将对确保各个领域的可靠和高效通信至关重要。