intercarrier distance

简明释义

载波间距离

英英释义

例句

1.The engineers measured the intercarrier distance to ensure proper alignment of the antennas.

工程师测量了载波间距以确保天线的正确对齐。

2.Adjusting the intercarrier distance can significantly improve signal quality.

调整载波间距可以显著提高信号质量。

3.To optimize performance, the team experimented with different intercarrier distances.

为了优化性能，团队尝试了不同的载波间距。

4.The specification requires an intercarrier distance of at least 10 meters.

该规范要求至少有10米的载波间距。

5.In telecommunications, the intercarrier distance is crucial for minimizing interference.

在电信中，载波间距对于最小化干扰至关重要。

作文

In the field of telecommunications and wireless communication systems, the term intercarrier distance is crucial for understanding how signals are transmitted and received effectively. The intercarrier distance refers to the physical space between two carriers or transmission points in a network. This distance can significantly impact the quality and reliability of the communication link. When designing a wireless network, engineers must carefully consider the intercarrier distance to optimize signal strength and minimize interference.One of the primary factors that affect the intercarrier distance is the frequency of the signals being transmitted. Higher frequency signals tend to have shorter wavelengths, which means they can be affected more easily by obstacles such as buildings, trees, and other environmental factors. As a result, the intercarrier distance may need to be reduced to ensure that the signal remains strong enough to be received clearly at the destination. Conversely, lower frequency signals can travel longer distances and penetrate obstacles more effectively, allowing for a greater intercarrier distance without compromising signal quality.Another important consideration when evaluating intercarrier distance is the type of modulation used in the communication system. Different modulation techniques have varying levels of resilience to noise and interference. For example, some advanced modulation schemes can maintain a clear signal even at greater intercarrier distances, while simpler techniques may require closer proximity between carriers to function effectively.The deployment of multiple antennas, known as MIMO (Multiple Input Multiple Output) technology, has also changed the way we think about intercarrier distance. With MIMO systems, multiple signals can be transmitted and received simultaneously over the same frequency channel, which can enhance the overall capacity and reliability of the communication link. In this context, understanding the optimal intercarrier distance becomes even more critical, as it influences the performance of the MIMO system and its ability to mitigate interference.In practical applications, the concept of intercarrier distance is vital for various technologies, including cellular networks, Wi-Fi, and satellite communications. For instance, in cellular networks, base stations must be strategically placed to maintain an appropriate intercarrier distance that ensures coverage while minimizing overlap and interference between adjacent cells. Similarly, in Wi-Fi networks, the placement of routers and access points should take into account the intercarrier distance to provide optimal signal strength throughout the coverage area.Moreover, the intercarrier distance can also play a role in the design of new technologies such as 5G and beyond. As these networks aim to provide higher data rates and lower latency, understanding and optimizing the intercarrier distance will be essential for achieving the desired performance metrics. Engineers and researchers continually explore innovative solutions to manage the challenges associated with intercarrier distance, ensuring that future communication systems can meet the growing demands of users worldwide.In conclusion, the term intercarrier distance is a fundamental concept in telecommunications that encompasses various aspects of signal transmission and reception. By understanding the implications of intercarrier distance on signal quality, modulation techniques, and network design, professionals in the field can create more efficient and reliable communication systems. As technology continues to evolve, the importance of optimizing intercarrier distance will only increase, paving the way for advancements in connectivity and communication capabilities.

在电信和无线通信系统领域，术语intercarrier distance对于理解信号如何有效传输和接收至关重要。intercarrier distance指的是网络中两个载波或传输点之间的物理空间。这一距离会显著影响通信链路的质量和可靠性。在设计无线网络时，工程师必须仔细考虑intercarrier distance以优化信号强度并最小化干扰。影响intercarrier distance的主要因素之一是所传输信号的频率。高频信号通常具有较短的波长，这意味着它们更容易受到建筑物、树木和其他环境因素等障碍物的影响。因此，可能需要减少intercarrier distance以确保信号在目的地仍然足够强，以便清晰接收。相反，低频信号可以传播更远的距离，并更有效地穿透障碍物，从而在不影响信号质量的情况下允许更大的intercarrier distance。评估intercarrier distance时，另一个重要的考虑因素是通信系统中使用的调制类型。不同的调制技术对噪声和干扰的抵抗能力各不相同。例如，一些先进的调制方案即使在较大的intercarrier distance下也能保持清晰的信号，而简单的技术可能要求载波之间的距离更近才能有效工作。多天线部署，即MIMO（多输入多输出）技术，也改变了我们对intercarrier distance的思考方式。通过MIMO系统，可以在同一频率通道上同时传输和接收多个信号，从而增强通信链路的整体容量和可靠性。在这种情况下，了解最佳的intercarrier distance变得更加关键，因为它影响MIMO系统的性能及其减轻干扰的能力。在实际应用中，intercarrier distance的概念对多种技术至关重要，包括蜂窝网络、Wi-Fi和卫星通信。例如，在蜂窝网络中，基站必须战略性地布置，以维持适当的intercarrier distance，确保覆盖范围，同时最小化相邻小区之间的重叠和干扰。同样，在Wi-Fi网络中，路由器和接入点的放置应考虑到intercarrier distance，以在覆盖区域内提供最佳的信号强度。此外，intercarrier distance在5G及更高版本等新技术的设计中也发挥着作用。随着这些网络旨在提供更高的数据速率和更低的延迟，理解和优化intercarrier distance对于实现所需的性能指标至关重要。工程师和研究人员不断探索创新解决方案，以管理与intercarrier distance相关的挑战，确保未来的通信系统能够满足全球用户日益增长的需求。总之，术语intercarrier distance是电信中的一个基本概念，涵盖了信号传输和接收的各个方面。通过理解intercarrier distance对信号质量、调制技术和网络设计的影响，行业专业人士可以创建更高效、更可靠的通信系统。随着技术的不断发展，优化intercarrier distance的重要性只会增加，为连接和通信能力的进步铺平道路。