error protected transmission system

简明释义

防误传送方式

英英释义

例句

1.The new satellite communication system utilizes an error protected transmission system to ensure data integrity.

新的卫星通信系统利用错误保护传输系统来确保数据的完整性。

2.Implementing an error protected transmission system can significantly improve the reliability of our services.

实施错误保护传输系统可以显著提高我们服务的可靠性。

3.Our company's network relies on an error protected transmission system to maintain secure communications.

我们公司的网络依赖于错误保护传输系统来保持安全通信。

4.In modern telecommunications, an error protected transmission system is essential for minimizing data loss.

在现代电信中，错误保护传输系统对于减少数据丢失至关重要。

5.The error protected transmission system in this device helps prevent issues during long-distance data transfer.

该设备中的错误保护传输系统有助于防止长距离数据传输中的问题。

作文

In the rapidly evolving world of technology, communication systems are becoming increasingly complex and essential. One key aspect of these systems is the ability to transmit data reliably and accurately. This is where the concept of an error protected transmission system comes into play. An error protected transmission system (错误保护传输系统) ensures that the data sent from one point to another remains intact and free from errors, despite potential interferences or disruptions during the transmission process. The importance of an error protected transmission system cannot be overstated, especially in critical applications such as telecommunications, data storage, and broadcasting. For instance, in telecommunications, a single error in data transmission can lead to dropped calls or poor-quality audio. By implementing an error protected transmission system, companies can significantly reduce the chances of such errors occurring, thereby enhancing the overall quality of service provided to their customers.There are several techniques used to create an error protected transmission system. One common method is the use of error-correcting codes, which add redundant information to the original data being transmitted. This redundancy allows the receiving end to detect and correct errors without needing to request the data to be sent again. Another approach is the use of checksums or cyclic redundancy checks (CRC), which involve calculating a value based on the data being sent. The receiving system can then verify the integrity of the received data by comparing this calculated value with the one sent along with the data.Moreover, the implementation of an error protected transmission system is not limited to just the transmission phase; it also encompasses the entire process of data handling. This means that even before data is transmitted, it can be subjected to various forms of validation and error-checking mechanisms to ensure its accuracy. For example, data can be validated at the source to eliminate any potential errors before it even begins its journey through the transmission system.In addition to telecommunications, error protected transmission systems are crucial in fields such as satellite communications and computer networking. In satellite communications, signals must travel vast distances, and any interference can lead to significant data loss. An error protected transmission system helps to maintain the integrity of these signals, ensuring that the information reaches its destination as intended. Similarly, in computer networking, where multiple devices communicate over various channels, having a robust error protected transmission system is vital for maintaining efficient and reliable data exchange.As technology continues to advance, the demand for more sophisticated error protected transmission systems will only grow. Innovations such as machine learning and artificial intelligence are beginning to play a role in enhancing these systems, allowing for smarter error detection and correction methods. The future of communication technology hinges on our ability to develop and implement effective error protected transmission systems that can keep pace with the increasing volume and complexity of data being transmitted.In conclusion, the role of an error protected transmission system (错误保护传输系统) is vital in ensuring the reliability and accuracy of data transmission across various platforms. As we continue to rely on technology for communication, understanding and improving these systems will be essential for achieving seamless and error-free interactions in our increasingly digital world.

在快速发展的技术世界中，通信系统变得越来越复杂且至关重要。这些系统的一个关键方面是能够可靠和准确地传输数据。这就是错误保护传输系统的概念发挥作用的地方。错误保护传输系统确保从一个点发送到另一个点的数据保持完整并且没有错误，尽管在传输过程中可能会有干扰或中断。错误保护传输系统的重要性不容小觑，尤其是在电信、数据存储和广播等关键应用中。例如，在电信中，数据传输中的单个错误可能导致通话中断或音频质量差。通过实施错误保护传输系统，公司可以显著减少此类错误发生的机会，从而提高提供给客户的整体服务质量。创建错误保护传输系统有几种技术。其中一种常见的方法是使用错误更正代码，这些代码将冗余信息添加到正在传输的原始数据中。这种冗余允许接收端检测和纠正错误，而无需请求重新发送数据。另一种方法是使用校验和或循环冗余检查（CRC），这涉及根据所发送的数据计算一个值。接收系统可以通过将该计算值与随数据一起发送的值进行比较，从而验证接收到的数据的完整性。此外，实施错误保护传输系统不仅限于传输阶段；它还涵盖整个数据处理过程。这意味着即使在数据传输之前，也可以对其进行各种形式的验证和错误检查机制，以确保其准确性。例如，可以在源头验证数据，以消除在数据开始通过传输系统之前的任何潜在错误。除了电信之外，错误保护传输系统在卫星通信和计算机网络等领域也至关重要。在卫星通信中，信号必须穿越广阔的距离，任何干扰都可能导致重大的数据丢失。错误保护传输系统有助于保持这些信号的完整性，确保信息按预期到达目的地。同样，在计算机网络中，多个设备通过各种通道进行通信，拥有强大的错误保护传输系统对于维护高效和可靠的数据交换至关重要。随着技术的不断进步，对更复杂的错误保护传输系统的需求只会增长。机器学习和人工智能等创新开始在增强这些系统方面发挥作用，使得更智能的错误检测和更正方法成为可能。通信技术的未来依赖于我们开发和实施有效的错误保护传输系统的能力，以跟上传输数据的数量和复杂性日益增加的步伐。总之，错误保护传输系统（错误保护传输系统）在确保各种平台上数据传输的可靠性和准确性方面发挥着至关重要的作用。随着我们继续依赖技术进行通信，理解和改善这些系统对于在我们日益数字化的世界中实现无缝和无错误的互动至关重要。