carrier power output

简明释义

载波输出功率

英英释义

例句

1.During the test, the carrier power output was found to be below the acceptable threshold.

在测试过程中，发现载波功率输出低于可接受的阈值。

2.The carrier power output directly influences the quality of the audio transmitted over the radio.

在无线电中，载波功率输出直接影响传输音频的质量。

3.Increasing the carrier power output can help improve the coverage area of the network.

增加载波功率输出可以帮助改善网络的覆盖范围。

4.Adjustments to the carrier power output are necessary to optimize the performance of the transmitter.

调整载波功率输出是优化发射器性能所必需的。

5.The technician measured the carrier power output to ensure the signal strength was adequate for communication.

技术人员测量了载波功率输出以确保信号强度足够用于通信。

作文

In the realm of telecommunications, the term carrier power output refers to the amount of power that a transmitter delivers to the antenna for broadcasting signals. This measurement is crucial because it directly affects the range and quality of the signal transmitted. The carrier power output can influence various aspects of communication systems, including signal strength, interference levels, and overall system performance. Understanding this concept is essential for engineers and technicians working in the field of radio frequency (RF) communications.When discussing carrier power output, it's important to consider the factors that contribute to its effectiveness. For instance, the type of modulation used can greatly impact the efficiency of the power being transmitted. Different modulation schemes, such as amplitude modulation (AM) or frequency modulation (FM), have distinct characteristics that may require adjustments in the carrier power output to achieve optimal performance. Therefore, engineers must carefully analyze the requirements of their specific application to determine the appropriate level of power output.Moreover, the carrier power output is not just about raw power; it is also about how that power is utilized. In many cases, the goal is to maximize the coverage area while minimizing interference with other channels. This balancing act requires a deep understanding of radio wave propagation and environmental factors that can affect signal transmission. For example, geographical features such as mountains or buildings can obstruct signals, necessitating higher carrier power output to maintain effective communication.Another critical aspect of carrier power output is its relationship with energy efficiency. In an era where sustainability is becoming increasingly important, optimizing the power output of transmission systems can lead to significant energy savings. Engineers are tasked with designing systems that not only meet the necessary power output requirements but also do so in an energy-efficient manner. This often involves the implementation of advanced technologies that can dynamically adjust the carrier power output based on real-time conditions, ensuring that power is used effectively without compromising signal quality.Furthermore, regulatory considerations play a vital role in determining the carrier power output. Different countries and regions have specific regulations governing the maximum allowable power output for various types of communication systems. Compliance with these regulations is essential to avoid interference with other services and to ensure the safety and reliability of communication networks. Engineers must stay informed about these regulations and design their systems accordingly, which often involves conducting thorough testing and validation of the carrier power output.In conclusion, the concept of carrier power output is fundamental to the field of telecommunications. It encompasses a range of considerations, from technical aspects like modulation and signal propagation to practical concerns regarding energy efficiency and regulatory compliance. A thorough understanding of carrier power output allows engineers and technicians to design effective communication systems that meet the demands of modern society while minimizing environmental impact. As technology continues to evolve, the importance of optimizing carrier power output will only grow, making it a key focus area for future innovations in telecommunications.

在电信领域，术语载波功率输出指的是发射机传递给天线以广播信号的功率。这个测量非常重要，因为它直接影响到所传输信号的范围和质量。载波功率输出可以影响通信系统的各个方面，包括信号强度、干扰水平和整体系统性能。理解这个概念对于在射频（RF）通信领域工作的工程师和技术人员至关重要。在讨论载波功率输出时，考虑影响其有效性的因素是非常重要的。例如，使用的调制类型会极大地影响传输功率的效率。不同的调制方案，如幅度调制（AM）或频率调制（FM），具有不同的特性，可能需要调整载波功率输出以实现最佳性能。因此，工程师必须仔细分析其特定应用的要求，以确定适当的功率输出水平。此外，载波功率输出不仅仅关乎原始功率；它还关乎如何利用该功率。在许多情况下，目标是在最小化与其他频道的干扰的同时最大化覆盖区域。这种平衡行为需要对无线波传播和环境因素有深入的了解，这些因素可能会影响信号传输。例如，地理特征如山脉或建筑物可能会阻碍信号，因此需要更高的载波功率输出来保持有效的通信。载波功率输出的另一个关键方面是其与能源效率的关系。在可持续性日益重要的时代，优化传输系统的功率输出可以带来显著的节能效果。工程师的任务是设计出不仅满足必要功率输出要求，而且以节能的方式做到这一点的系统。这通常涉及实施先进技术，可以根据实时条件动态调整载波功率输出，确保有效利用功率而不妨碍信号质量。此外，监管考虑在确定载波功率输出时也发挥着重要作用。不同国家和地区对各种类型通信系统的最大允许功率输出有具体规定。遵守这些规定对于避免与其他服务的干扰以及确保通信网络的安全和可靠至关重要。工程师必须及时了解这些规定，并相应设计他们的系统，这通常涉及对载波功率输出进行彻底测试和验证。总之，载波功率输出的概念是电信领域的基础。它涵盖了一系列考虑因素，从调制和信号传播等技术方面，到能源效率和监管合规等实际问题。透彻理解载波功率输出使工程师和技术人员能够设计出有效的通信系统，满足现代社会的需求，同时最小化环境影响。随着技术的不断发展，优化载波功率输出的重要性只会增加，使其成为未来电信创新的关键关注领域。