Abstract :
Given the parallels between the complexity of human spaceflight and large software systems, there are many things we developers can learn from successful space programs, such as the Soyuz. First, limiting a project´s scope and complexity early on can have a dramatic payoff in its success and longevity. In addition, adding generous margins to early estimates (and any subsequent revisions) will ease the pain of development and deployment. Furthermore, gradual evolution with a working program at each step, rather than massive rewrites, benefits from successful architectures and teams, while also retaining the software´s customer base and third-party contributors. Finally, a well-defined modular structure can increase the software´s versatility yielding economies of scope and scale over its lifetime.
Keywords :
aerospace computing; computational complexity; software architecture; human spaceflight complexity; massive rewrites; software customer base; software systems; software versatility; space programs; third-party contributors; Pareto optimization; Software development; Space missions; System analysis and design; Pareto´s law; Soyuz; Space Shuttle; agility; agradual improvement; estimation techniques; modularity; safety margins;
