pulse transmission

简明释义

脉冲传输

英英释义

例句

1.During the experiment, we analyzed the effects of pulse transmission on signal clarity.

在实验中，我们分析了脉冲传输对信号清晰度的影响。

2.The new medical device utilizes pulse transmission to monitor heart activity in real-time.

这款新医疗设备利用脉冲传输实时监测心脏活动。

3.The robotics team implemented pulse transmission to enhance communication between robots.

机器人团队实施了脉冲传输以增强机器人之间的通信。

4.In telecommunications, pulse transmission is essential for sending data over long distances.

在电信中，脉冲传输对于长距离数据传输至关重要。

5.The engineers improved the efficiency of pulse transmission in the fiber optic network.

工程师们提高了光纤网络中脉冲传输的效率。

作文

In the realm of modern communication and technology, the concept of pulse transmission plays a pivotal role. Pulse transmission refers to the method of sending information through discrete pulses, which can be either electrical or optical signals. This technique is fundamental in various applications, including telecommunications, data networking, and even medical devices. Understanding pulse transmission is essential for anyone looking to delve into these fields, as it forms the backbone of how data is transferred efficiently and reliably.To grasp the significance of pulse transmission, we must first explore its basic principles. At its core, pulse transmission involves encoding information into a series of pulses that represent binary data. Each pulse corresponds to a specific value, typically a '1' or '0', allowing complex information to be simplified into manageable units. This binary system is the foundation of digital communication, enabling devices to interpret and process data accurately.One of the most notable applications of pulse transmission is in fiber optic communication. In this context, light pulses are transmitted through optical fibers, allowing for high-speed data transfer over long distances. The use of light as a medium for pulse transmission offers several advantages, including reduced signal degradation and immunity to electromagnetic interference. As a result, fiber optic networks have become the backbone of internet infrastructure, facilitating the rapid exchange of information across the globe.Moreover, pulse transmission is not limited to optical signals; it is also widely used in electronic communications. For instance, in traditional telephone systems, voice signals are converted into electrical pulses that travel over copper wires. This method of pulse transmission allows for clear audio communication, even over vast distances. The efficiency of this system has paved the way for advancements in mobile communication, where similar principles are employed to transmit voice and data signals wirelessly.In addition to telecommunications, pulse transmission is crucial in medical technology. Devices such as electrocardiograms (ECGs) utilize pulse transmission to monitor heart activity by converting electrical signals generated by the heart into readable data. This ability to transmit precise pulse signals enables healthcare professionals to diagnose and treat patients effectively. The implications of pulse transmission in medicine highlight its importance beyond just communication; it is a vital component in saving lives.Furthermore, the future of pulse transmission looks promising with the advent of new technologies such as 5G networks and the Internet of Things (IoT). These innovations rely heavily on efficient pulse transmission to connect billions of devices and facilitate instantaneous communication. As we continue to advance technologically, the demand for faster and more reliable pulse transmission methods will only grow, driving research and development in this field.In conclusion, pulse transmission is a fundamental concept that underpins many aspects of modern technology. From telecommunications to medical devices, the ability to transmit information through discrete pulses is essential for efficient communication. As we move forward into an increasingly connected world, understanding and improving pulse transmission will be crucial for the continued advancement of technology and its applications in our daily lives.

在现代通信和技术领域，脉冲传输的概念发挥着关键作用。脉冲传输是指通过离散脉冲发送信息的方法，这些脉冲可以是电信号或光信号。这种技术在各种应用中至关重要，包括电信、数据网络甚至医疗设备。理解脉冲传输对于任何希望深入这些领域的人来说都是必不可少的，因为它构成了数据高效可靠传输的基础。要理解脉冲传输的重要性，我们首先必须探讨其基本原理。在其核心，脉冲传输涉及将信息编码为一系列脉冲，这些脉冲代表二进制数据。每个脉冲对应一个特定值，通常是“1”或“0”，使复杂的信息简化为可管理的单元。这种二进制系统是数字通信的基础，使设备能够准确地解释和处理数据。脉冲传输的一个显著应用是在光纤通信中。在这种情况下，光脉冲通过光纤传输，允许高速数据在长距离上传输。使用光作为脉冲传输的媒介提供了几个优点，包括减少信号衰减和对电磁干扰的免疫。因此，光纤网络已成为互联网基础设施的支柱，促进了全球信息的快速交换。此外，脉冲传输不仅限于光信号；它在电子通信中也被广泛使用。例如，在传统电话系统中，语音信号被转换为电脉冲，通过铜线传输。这种脉冲传输的方法允许清晰的音频通信，即使在遥远的距离上。这一系统的高效性为移动通信的进步铺平了道路，在那里类似的原理被用于无线传输语音和数据信号。除了电信，脉冲传输在医疗技术中也至关重要。心电图（ECG）等设备利用脉冲传输监测心脏活动，通过将心脏产生的电信号转换为可读数据。这种精确脉冲信号的传输能力使医疗专业人员能够有效地诊断和治疗患者。脉冲传输在医学中的意义突显了它超越通信的重要性；它是拯救生命的关键组成部分。此外，随着5G网络和物联网（IoT）等新技术的出现，脉冲传输的未来看起来很有前景。这些创新在很大程度上依赖于高效的脉冲传输来连接数十亿设备并促进瞬时通信。随着我们继续在技术上进步，对更快和更可靠的脉冲传输方法的需求只会增长，从而推动该领域的研究和发展。总之，脉冲传输是支撑现代技术许多方面的基本概念。从电信到医疗设备，通过离散脉冲传输信息的能力对于高效通信至关重要。随着我们进入一个日益互联的世界，理解和改善脉冲传输将对技术的持续进步及其在我们日常生活中的应用至关重要。