航天系统工程(英文版)

航空航天相关英语词汇English: Aerospace engineering is the discipline that studies the design and development of aircraft and spacecraft. It involves a wide range of fields, including aerodynamics, structures, propulsion systems, control systems, materials science and engineering, and manufacturing processes. Aerospace engineers work on a variety of projects, from designing new aircraft or spacecraft to improving existing ones, as well as developing new technologies that can be used in aerospace applications. Some of the most common applications of aerospace engineering include the development of commercial airliners, military aircraft, rockets and missiles, and spacecraft for scientific research or exploration.Other important areas of study in aerospace engineering include space missions, atmospheric entry and re-entry, and the physical properties of fluids at high speeds and altitudes. In order to work in this field, it is usually necessary to have a degree in aerospace engineering or a related field, such as mechanical engineering or materials science. Additionally, many aerospace engineers will need to complete specialized training and certifications in areas such asaerospace systems testing, safety and reliability, and systems engineering.Chinese Translation: 航空航天工程学是研究飞行器和航天器的设计和开发的学科，涉及广泛的领域，包括空气动力学、结构、推进系统、控制系统、材料科学和工程以及制造工艺。

图书基本信息书名：<<NASA系统工程手册>>13位ISBN编号：978712118081110位ISBN编号：7121180812出版时间：2012-11出版时间：电子工业出版社作者：朱一凡　等页数：323字数：533000版权说明：本站所提供下载的PDF图书仅提供预览和简介，请支持正版图书。

更多资源请访问：内容概要 系统工程是分析解决复杂系统的论证、设计、生产和使用中的评价决策和权衡优化问题的有效方法和手段。

系统工程不仅有完整的理论方法和技术手段构成的科学体系，而且在像航天系统这样经费预算多、研制周期长、运行使用风险高的复杂系统中的具体应用又体现出多样性和复杂性。

如何有效地利用系统工程理论和方法针对复杂系统进行组织管理并达到预期的目的，需要对系统工程思想有深刻的理解和丰富的工程实践经验。

本手册是美国国家航空航宇局（NASA）对多年系统工程实践经验的总结，主要有三个部分的内容：第一部分（第1～3章）是结合航天产品的寿命周期介绍由多个系统工程流程构成的航天产品开发和控制管理的系统工程引擎，第二部分（第4～5章）针对系统工程引擎中的每个流程详细介绍流程实施的过程和指南，第三部分（第6～7章）介绍在开展系统工程工作时应当把握的关键技术和相关标准。

本手册内容翔实、图文并茂，许多问题的阐述结合实例，部分具体操作还在附录中给出了参考样板。

NASA系统工程手册不仅可以作为工业工程领域产品开发和系统工程组织管理实践的有益借鉴，也可以作为从事产品研发与项目管理的科技人员和高等院校系统工程专业或相近专业研究生和高年级本科生的学习参考。

书籍目录第1章 引言1.1 本手册的目的1.2 本手册的范围和深度1.3 关于NASA第2章 系统工程基础2.1 通用技术流程与系统工程引擎2.2 按照项目阶段概述系统工程引擎2.3 使用系统工程引擎的示例2.3.1 示例导言2.3.2 详细示例2.4 产品验证和产品确认的区别2.5 系统工程的费用第3章 NASA工程/项目寿命周期3.1 工程规划论证3.2 工程实施执行3.3 项目A前阶段：概念探索3.4 项目阶段A：概念研究和技术开发3.5 项目阶段B：初步设计和技术完善3.6 项目阶段C：详细设计和制造3.7 项目阶段D：系统组装、集成、试验和投产3.8 项目阶段E：运行使用与维护3.9 项目阶段F：退役处置3.10 经费：预算周期第4章 系统设计4.1 明确利益相关者的期望4.1.1 流程描述4.1.2 明确利益相关者期望流程指南4.2 技术需求定义4.2.1 流程描述4.2.2 技术需求定义指南4.3 逻辑分解4.3.1 流程描述4.3.2 逻辑分解指南4.4 设计方案定义4.4.1 流程描述4.4.2 设计方案定义指南第5章 产品实现5.1 产品实施执行5.1.1 流程描述5.1.2 产品实施执行指南5.2 产品集成5.2.1 流程描述5.2.2 产品集成指南5.3 产品验证5.3.1 流程描述5.3.2 产品验证指南5.4 产品确认5.4.1 流程描述5.4.2 产品确认指南5.5 产品交付5.5.1 流程描述5.5.2 产品交付指南第6章 技术管理6.1 技术规划6.1.1 流程描述6.1.2 技术规划指南6.2 需求管理6.2.1 流程描述6.2.2 需求管理指南6.3 接口管理6.3.1 流程描述6.3.2 接口管理指南6.4 技术风险管理6.4.1 流程描述6.4.2 技术风险管理指南6.5 技术状态管理6.5.1 流程描述6.5.2 技术状态管理指南6.6 技术数据管理6.6.1 流程描述6.6.2 技术数据管理指南6.7 技术评估6.7.1 流程描述6.7.2 技术评估指南6.8 决策分析6.8.1 流程描述6.8.2 决策分析指南第7章 相关专题7.1 与合同相关的工程技术7.1.1 引言、目的和范围7.1.2 采办策略7.1.3 签订合同前的工作7.1.4 履行合同期间7.1.5 合同完成7.2 一体化设计平台7.2.1 引言7.2.2 CACE概述及其重要性7.2.3 CACE目标和益处7.2.4 CACE人员组织7.2.5 CACE流程7.2.6 CACE工程的工具和技巧7.2.7 CACE设施、信息架构和人员组织7.2.8 CACE产品7.2.9 CACE最佳实践7.3 选择工程设计工具7.3.1 工程和项目考虑的事项7.3.2 政策和流程7.3.3 协同7.3.4 设计标准7.3.5 现有的信息体系结构7.3.6 工具接口7.3.7 互操作性和数据格式7.3.8 向后兼容性7.3.9 平台7.3.10 工具技术状态控制7.3.11 保密性/访问控制7.3.12 培训7.3.13 许可证7.3.14 供应商和用户保障的稳定性7.4 人因工程7.4.1 基础人因模型7.4.2 人因分析和评估技术7.5 环境、核安全、行星保护和资产保护政策约束7.5.1 国家环境政策法令和行政法令7.5.2 关于放射性物质的环境影响7.5.3 行星保护7.5.4 空间资产设施保护7.6 公制度量单位的使用附录A 缩略词附录B 专用词汇表附录C 如何撰写一个好的需求附录D 需求验证矩阵附录E 创建确认计划（包括需求确认矩阵）附录F 功能、时序和状态分析附录G 技术评估/技术引入附录H 集成计划概要附录I 验证和确认范例概要附录J 系统工程管理计划内容概要附录K 计划附录L 接口需求文档概要附录M 技术状态管理（CM）计划概要附录N 技术同行评审/检查附录O 权衡示例附录P 任务书（SOW）评审清单附录Q 项目防护规划概要分章节参考文献按作者参考文献章节摘录版权页： 插图： 许多参数费用模型可用于计算NASA系统成本。

NASA 系统工程手册是美国国家航空航天局（National Aeronautics and Space Administration）发布的一部权威性的技术指南，旨在为NASA工程师和项目团队提供规范的系统工程实践和流程。

该手册包含了广泛的系统工程知识，涵盖了系统工程的各个阶段和方面，是NASA工程师和项目团队的宝贵参考资料。

而2016年版本的NASA系统工程手册中英文版，是该手册的最新版，对之前版本进行了更新和修订，以适应当下的技术和实践需求。

该手册不仅从理论上系统分析了系统工程的基本概念和原则，还结合实际案例和经验，提供了丰富的技术指导和实践建议。

下面将对NASA系统工程手册2016 中英文版的内容进行逐项分析：一、前言该部分将对NASA系统工程手册的编纂目的、使用范围和读者对象进行介绍，以及对2016年版本进行了详细的绪论和说明。

在前言部分，读者可以了解到该手册的背景和意义，以及如何正确使用该手册。

二、概述概述部分将系统工程的概念和发展历程进行了阐述，对系统工程的重要性和必要性进行了充分的论证，为读者提供了对系统工程的整体认知和理解。

三、系统工程基础1. 系统工程的基本概念该部分对系统工程的基本概念进行了详细的阐述，包括系统、系统工程、系统工程过程等，在理论上为读者构建了系统工程的基础认知。

2. 系统工程原则系统工程原则是系统工程实践的指导原则，该部分详细介绍了系统工程的原则和方法，帮助读者了解系统工程的核心理念和实践要点。

3. 系统工程流程该部分将系统工程的各个阶段和流程进行了详细讲解，包括需求分析、设计、实施和验证等，帮助读者了解系统工程的具体操作步骤和工作流程。

四、NASA系统工程实践1. 系统工程管理系统工程管理是系统工程的重要组成部分，该部分介绍了NASA在系统工程实践中的管理方法和经验，为读者提供了可借鉴的管理经验和实践指导。

2. 系统工程分析系统工程分析是系统工程的核心内容之一，该部分介绍了NASA在系统工程分析方面的实践和经验，包括数据分析、模型构建和结果评估等内容。

中国航天计划英语作文简单China's Space Program: Exploring the Final Frontier。

China's space program has garnered global attention for its ambitious goals, technological advancements, and remarkable achievements. From launching satellites into orbit to landing rovers on the Moon and Mars, China has been steadily expanding its presence in outer space. Inthis essay, we will delve into the key components and accomplishments of China's space program.First and foremost, China's space program is driven by its long-term vision of becoming a leading spacefaring nation. The program is overseen by the China National Space Administration (CNSA), which coordinates various space missions and activities. CNSA's objectives encompass both scientific exploration and technological innovation, with a focus on enhancing national prestige and fostering economic development.One of the cornerstones of China's space program is its human spaceflight initiative. In 2003, China achieved a historic milestone by sending its first astronaut, Yang Liwei, into space aboard the Shenzhou 5 spacecraft. Since then, China has conducted several crewed missions,including spacewalks and the establishment of a space laboratory called Tiangong ("Heavenly Palace"). These endeavors have demonstrated China's ability to sustain human presence in space and laid the groundwork for future endeavors such as constructing a permanent space station.In addition to crewed missions, China has made significant strides in robotic exploration. The Chang'e program, named after the Chinese goddess of the Moon, has been instrumental in advancing lunar exploration. China became the third country to successfully soft-land a spacecraft on the Moon with the Chang'e 3 mission in 2013, which deployed the Yutu rover to explore the lunar surface. Subsequent missions, including Chang'e 4 and Chang'e 5, further expanded China's lunar capabilities, with objectives ranging from studying the Moon's geology to collecting and returning lunar samples to Earth.Moreover, China's space program has set its sights on the Red Planet. The Tianwen-1 mission, launched in 2020, represents China's first independent interplanetary expedition. Consisting of an orbiter, a lander, and a rover, Tianwen-1 aims to explore Mars comprehensively, conducting remote sensing, topographic mapping, and surface exploration. If successful, China will join an elite groupof nations that have successfully reached and operated on Mars.Furthermore, China's space program encompasses a wide range of scientific research and technological development initiatives. These include the development of advanced launch vehicles, satellite systems for communication and Earth observation, and experiments conducted aboard the Tiangong space station. China's investments in space technology have not only bolstered its domesticcapabilities but have also positioned the country as a key player in the global space industry.However, China's space ambitions have not been withoutchallenges and controversies. The country's rapid advancements in space technology have raised concerns among some international observers, particularly regarding issues of military applications and space debris. Moreover,China's exclusion from certain international collaborations, such as the International Space Station (ISS), has prompted calls for greater cooperation and transparency in space activities.In conclusion, China's space program stands as a testament to the country's scientific and technological prowess, as well as its aspirations for leadership in space exploration. With a diverse portfolio of missions and a commitment to innovation, China continues to push the boundaries of what is possible in outer space. As the country looks toward the future, it remains poised to make further contributions to humanity's understanding of the cosmos.。

完整版)航空航天英语词汇(较全)Manned space flight。

also known as multi-manned and multi-day space flight。

is a crucial part of the manned space program。

The space shuttle is a type of manned spaceship used for this purpose。

while XXX。

The Long March II F carrier rocket is an example of such a rocket with a high payload capability.Once in orbit。

XXX。

XXX。

XXX。

and remote XXX。

These can be placed in different types of orbits。

such as the Sun-XXX.XXX consists of multiple modules。

including the orbital module。

re-entry module。

propelling module。

and command module。

These modules work together to ensure the safety and success of the n.The Service Module。

Lunar Module。

and Launch Pad are all crucial components of space travel。

In case of emergencies。

XXX includes the study of space physics and the nal Space n。

which relies on Solar Panels for power。

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