parallel system

简明释义

并联系统平行系统

英英释义

例句

1.The company implemented a parallel system to enhance data processing efficiency.

公司实施了一个并行系统来提高数据处理效率。

2.The parallel system allows multiple users to access the database simultaneously.

这个并行系统允许多个用户同时访问数据库。

3.The engineering team designed a parallel system to improve performance in simulations.

工程团队设计了一个并行系统以提高模拟中的性能。

4.By utilizing a parallel system, we can reduce processing time significantly.

通过利用一个并行系统，我们可以显著减少处理时间。

5.In the new software update, we introduced a parallel system for better load balancing.

在新的软件更新中，我们引入了一个并行系统以更好地进行负载均衡。

作文

In today's fast-paced world, the demand for efficiency and reliability in various systems is greater than ever. One concept that has gained significant attention in recent years is the parallel system (并行系统). A parallel system refers to a configuration where multiple components or processes operate simultaneously to achieve a common goal. This approach is particularly beneficial in fields such as computing, engineering, and telecommunications, where the need for speed and redundancy is paramount.The primary advantage of a parallel system lies in its ability to enhance performance. For instance, in computer processing, traditional serial systems execute tasks one after another, which can lead to bottlenecks and delays. In contrast, a parallel system allows for multiple processors to work on different parts of a task at the same time, significantly reducing the overall time required to complete complex computations. This is especially evident in applications such as data analysis, where large datasets can be processed much faster through parallel processing techniques.Moreover, parallel systems offer increased reliability. In many scenarios, having multiple components functioning in parallel means that if one component fails, others can continue to operate, thereby preventing total system failure. This redundancy is crucial in critical applications such as aerospace and medical devices, where system failure can have catastrophic consequences. By employing a parallel system, organizations can ensure higher availability and resilience in their operations.Another area where parallel systems play a vital role is in telecommunications. Modern communication networks often rely on parallel architectures to handle vast amounts of data traffic. By distributing data across multiple channels, these systems can maintain high levels of performance even during peak usage times. This capability is essential for providing reliable internet services and ensuring seamless communication between users.Despite the numerous benefits, implementing a parallel system also comes with its challenges. One significant issue is the complexity of designing and managing such systems. Coordinating multiple processes requires sophisticated algorithms and careful consideration of how tasks are divided and managed. Additionally, not all problems can be efficiently parallelized; some tasks inherently require sequential processing, which can limit the effectiveness of a parallel system.Furthermore, there are considerations regarding resource allocation and synchronization among parallel components. Ensuring that all parts of the parallel system work harmoniously without conflicts or deadlocks can be a daunting task. Developers must account for these factors when designing software that operates within a parallel system, making it crucial to have a solid understanding of concurrency and parallelism.In conclusion, the concept of a parallel system (并行系统) is integral to improving efficiency and reliability across various industries. By allowing multiple components to operate simultaneously, these systems can significantly enhance performance while providing redundancy to safeguard against failures. However, the complexities involved in designing and managing parallel systems cannot be overlooked. As technology continues to evolve, the importance of mastering parallel systems will only grow, paving the way for innovations that can transform how we approach problem-solving in an increasingly interconnected world.

在当今快速发展的世界中，各种系统对效率和可靠性的需求比以往任何时候都要高。近年来，一个备受关注的概念是并行系统。并行系统指的是多个组件或过程同时运行以实现共同目标的配置。这种方法在计算、工程和电信等领域尤为有利，因为这些领域对速度和冗余的需求至关重要。并行系统的主要优势在于其提高性能的能力。例如，在计算机处理方面，传统的串行系统一个接一个地执行任务，这可能导致瓶颈和延迟。相比之下，并行系统允许多个处理器同时处理任务的不同部分，从而显著减少完成复杂计算所需的整体时间。这在数据分析等应用中尤为明显，使用并行处理技术可以更快地处理大型数据集。此外，并行系统还提供了更高的可靠性。在许多情况下，多个组件并行工作意味着如果一个组件失败，其他组件仍然可以继续运行，从而防止整个系统崩溃。这种冗余在航空航天和医疗设备等关键应用中至关重要，因为系统故障可能会造成灾难性的后果。通过采用并行系统，组织可以确保其操作的更高可用性和弹性。并行系统在电信领域也发挥着重要作用。现代通信网络通常依赖并行架构来处理大量数据流量。通过将数据分配到多个通道，这些系统即使在高峰使用时也能保持高水平的性能。这种能力对于提供可靠的互联网服务和确保用户之间的无缝通信至关重要。尽管有许多好处，但实施并行系统也面临挑战。一个重大问题是设计和管理此类系统的复杂性。协调多个过程需要复杂的算法，并仔细考虑如何划分和管理任务。此外，并非所有问题都可以有效地并行化；某些任务本质上需要顺序处理，这可能限制并行系统的有效性。此外，还有资源分配和并行组件之间同步的考虑。确保并行系统的所有部分和谐工作而不发生冲突或死锁可能是一项艰巨的任务。开发人员在设计在并行系统内运行的软件时，必须考虑这些因素，因此对并发性和并行性的深入理解至关重要。总之，并行系统（并行系统）的概念对于提高各行业的效率和可靠性至关重要。通过允许多个组件同时运行，这些系统可以显著提高性能，同时提供冗余以防止故障。然而，设计和管理并行系统的复杂性不可忽视。随着技术的不断发展，掌握并行系统的重要性只会增加，为我们在日益互联的世界中解决问题的方法带来创新。