transmission cycle

简明释义

传输周期

英英释义

例句

1.Engine performance can be optimized by adjusting the transmission cycle settings.

通过调整传动周期设置，可以优化发动机性能。

2.In a manual transmission, the transmission cycle is controlled by the driver’s shifting patterns.

在手动变速器中，传动周期由驾驶员的换挡模式控制。

3.The transmission cycle affects how quickly power is delivered to the wheels.

传动周期影响动力传递到车轮的速度。

4.Understanding the transmission cycle can help in diagnosing issues with the gearbox.

理解传动周期有助于诊断变速箱的问题。

5.The efficiency of the vehicle largely depends on the length of its transmission cycle.

车辆的效率在很大程度上取决于其传动周期的长度。

作文

The concept of the transmission cycle is crucial in understanding how information or energy is transferred from one point to another. In various fields, including engineering, telecommunications, and biology, the transmission cycle plays a significant role in ensuring efficiency and effectiveness in processes. This essay will explore the definition, importance, and applications of the transmission cycle, providing insights into its multifaceted nature.To begin with, the transmission cycle can be defined as the series of steps or stages involved in the transfer of data, signals, or energy. This cycle typically includes phases such as initiation, propagation, reception, and processing. Each phase is essential for the successful transmission of information or energy, and any disruption in this cycle can lead to inefficiencies or failures in communication systems.In telecommunications, for instance, the transmission cycle is fundamental to the functioning of networks. When a user sends a message, the process begins with the initiation phase, where the message is encoded into a format suitable for transmission. Next, during the propagation phase, the encoded message travels through various mediums, such as cables or wireless channels. Upon reaching the recipient, the message undergoes the reception phase, where it is decoded and interpreted. Finally, in the processing phase, the recipient can respond or take action based on the received information. Understanding this transmission cycle is vital for engineers and technicians who aim to optimize network performance and minimize latency.Moreover, the transmission cycle also has significant implications in biological systems. For example, in the context of cellular communication, the transmission cycle refers to the way cells send and receive signals to coordinate functions. This cycle involves the release of signaling molecules, their travel to target cells, and the subsequent response by those cells. Disruptions in this cycle can lead to various health issues, including diseases such as cancer, where cell communication becomes aberrant. Thus, understanding the transmission cycle in biology is essential for developing targeted therapies and treatments.Furthermore, the transmission cycle is not limited to technical or biological contexts; it also applies to social interactions and information dissemination. In the age of digital communication, the transmission cycle encompasses the way information is shared across social media platforms. When a post is created, it goes through a similar cycle: it is generated, shared, propagated through networks, received by followers, and processed through likes, comments, or shares. The effectiveness of this cycle can significantly influence public opinion and behavior, highlighting the importance of understanding how information spreads in our interconnected world.In conclusion, the transmission cycle is a fundamental concept that transcends various disciplines, from engineering to biology and social sciences. By comprehensively understanding this cycle, we can enhance our ability to communicate effectively, improve technological systems, and address challenges in health and society. As we continue to advance in these fields, the study of the transmission cycle will remain pivotal in driving innovation and fostering better connections among individuals and systems.

“传输周期”的概念对于理解信息或能量如何从一个点转移到另一个点至关重要。在工程、电信和生物学等多个领域，“传输周期”在确保过程的效率和有效性方面发挥着重要作用。本文将探讨“传输周期”的定义、重要性和应用，提供对其多面性的深入见解。首先，“传输周期”可以定义为数据、信号或能量传递过程中涉及的一系列步骤或阶段。这个周期通常包括启动、传播、接收和处理等阶段。每个阶段对于信息或能量的成功传输都是必要的，任何对这一周期的干扰都可能导致通信系统中的低效或失败。例如，在电信中，“传输周期”是网络功能的基础。当用户发送消息时，过程始于启动阶段，在此阶段，消息被编码为适合传输的格式。接下来，在传播阶段，编码后的消息通过各种媒介（如电缆或无线通道）进行传输。到达接收者后，消息经历接收阶段，在此阶段，消息被解码和解释。最后，在处理阶段，接收者可以根据接收到的信息做出回应或采取行动。理解这一“传输周期”对于希望优化网络性能和最小化延迟的工程师和技术人员至关重要。此外，“传输周期”在生物系统中也具有重要意义。例如，在细胞通信的背景下，“传输周期”指的是细胞发送和接收信号以协调功能的方式。这个周期包括信号分子的释放，它们向目标细胞的移动，以及这些细胞随后的反应。该周期中的干扰可能导致各种健康问题，包括癌症等疾病，其中细胞通信变得异常。因此，了解生物学中的“传输周期”对开发针对性疗法和治疗至关重要。此外，“传输周期”并不限于技术或生物学的上下文；它还适用于社会互动和信息传播。在数字通信时代，“传输周期”涵盖了信息如何在社交媒体平台上共享。当创建帖子时，它经历类似的周期：生成、分享、通过网络传播、被关注者接收，并通过点赞、评论或分享进行处理。这个周期的有效性可以显著影响公众舆论和行为，突显了理解信息在我们相互关联的世界中传播方式的重要性。总之，“传输周期”是一个超越多个学科的基本概念，从工程到生物学再到社会科学。通过全面理解这一周期，我们可以增强有效沟通的能力，改善技术系统，并解决健康和社会中的挑战。随着我们在这些领域的持续进步，对“传输周期”的研究将继续在推动创新和促进个人与系统之间更好连接方面发挥关键作用。