multifrequency transmission

简明释义

多频发射

英英释义

例句

1.The satellite uses multifrequency transmission to provide better coverage and reduce interference.

卫星使用多频率传输来提供更好的覆盖并减少干扰。

2.The new communication system utilizes multifrequency transmission to enhance signal clarity.

新通信系统利用多频率传输来增强信号清晰度。

3.By implementing multifrequency transmission, the system achieved a higher data rate.

通过实施多频率传输，系统实现了更高的数据传输速率。

4.With multifrequency transmission, we can transmit data over various channels simultaneously.

通过多频率传输，我们可以同时在多个通道上传输数据。

5.The research team is exploring the benefits of multifrequency transmission in wireless networks.

研究团队正在探索多频率传输在无线网络中的好处。

作文

In today's rapidly evolving technological landscape, the concept of multifrequency transmission has emerged as a critical component in various fields, particularly in telecommunications and data transfer. This technique allows for the simultaneous transmission of multiple frequencies over a single communication channel, thereby enhancing the efficiency and capacity of data transfer. The ability to send and receive information across different frequencies enables more robust communication systems that can handle a larger volume of data without significant degradation in quality.The importance of multifrequency transmission is evident in modern wireless communication systems, such as cellular networks and Wi-Fi technologies. These systems rely on the ability to transmit data across various frequency bands to avoid congestion and interference. For instance, in a crowded urban environment, multiple devices are often trying to connect to the same network. By utilizing multifrequency transmission, these networks can efficiently allocate bandwidth, ensuring that each device receives a stable and fast connection.Moreover, multifrequency transmission plays a vital role in improving the performance of radar and sonar systems. These systems use different frequencies to detect objects and measure distances, allowing for greater accuracy and reliability in navigation and surveillance. By employing multiple frequencies, radar systems can better penetrate various materials and overcome obstacles, leading to enhanced detection capabilities in challenging environments.In addition to telecommunications and radar, multifrequency transmission is also significant in medical imaging technologies. Techniques such as ultrasound utilize multiple frequencies to create detailed images of internal organs and tissues. This multifrequency approach allows healthcare professionals to obtain clearer and more comprehensive diagnostic information, ultimately improving patient care.The implementation of multifrequency transmission is not without its challenges. Engineers and scientists must carefully design systems that can manage and process multiple frequency signals simultaneously. Issues such as signal interference and noise can arise, which may compromise the integrity of the transmitted data. However, advancements in technology and signal processing techniques continue to address these challenges, making multifrequency transmission an increasingly viable solution for modern communication needs.Looking towards the future, the potential applications of multifrequency transmission are vast and varied. As the demand for higher data rates and improved connectivity grows, this technique will likely become even more prevalent. Innovations in areas such as 5G technology and the Internet of Things (IoT) will further drive the need for efficient data transmission methods that can accommodate the increasing number of connected devices.In conclusion, the concept of multifrequency transmission represents a significant advancement in the field of communications and technology. Its ability to facilitate the simultaneous transmission of multiple frequencies enhances the capacity and efficiency of data transfer across various applications, from telecommunications to medical imaging. As we continue to push the boundaries of what is possible with technology, understanding and harnessing the power of multifrequency transmission will be essential for meeting the demands of an increasingly interconnected world.

在当今快速发展的技术环境中，“多频传输”的概念已成为各个领域的重要组成部分，尤其是在电信和数据传输方面。这种技术允许在单一通信通道上同时传输多个频率，从而提高数据传输的效率和容量。能够在不同频率上发送和接收信息，使得更强大的通信系统能够处理更大的数据量，而不会显著降低质量。“多频传输”的重要性在现代无线通信系统中显而易见，例如蜂窝网络和Wi-Fi技术。这些系统依赖于跨多个频段传输数据的能力，以避免拥塞和干扰。例如，在拥挤的城市环境中，多个设备通常试图连接到同一网络。通过利用“多频传输”，这些网络可以有效分配带宽，确保每个设备都能获得稳定且快速的连接。此外，“多频传输”在提高雷达和声纳系统的性能方面也发挥着至关重要的作用。这些系统使用不同的频率来探测物体和测量距离，从而在导航和监视中实现更高的准确性和可靠性。通过采用多个频率，雷达系统能够更好地穿透各种材料并克服障碍，从而在具有挑战性的环境中增强探测能力。除了电信和雷达，“多频传输”在医学成像技术中也具有重要意义。超声波等技术利用多个频率创建内部器官和组织的详细图像。这种多频率的方法使医疗专业人员能够获得更清晰、更全面的诊断信息，最终改善患者护理。“多频传输”的实施并非没有挑战。工程师和科学家必须仔细设计能够同时管理和处理多个频率信号的系统。信号干扰和噪声等问题可能会出现，这可能会影响传输数据的完整性。然而，技术和信号处理技术的进步不断解决这些挑战，使得“多频传输”成为满足现代通信需求的越来越可行的解决方案。展望未来，“多频传输”的潜在应用广泛而多样。随着对更高数据速率和改进连接性的需求增长，这种技术可能会变得更加普遍。在5G技术和物联网（IoT）等领域的创新将进一步推动对能够容纳越来越多连接设备的高效数据传输方法的需求。总之，“多频传输”的概念代表了通信和技术领域的一项重大进展。它能够促进多个频率的同时传输，提高了各个应用领域的数据传输容量和效率，从电信到医学成像。随着我们继续推动技术的边界，理解和利用“多频传输”的力量将对满足日益互联的世界的需求至关重要。