Systems engineering is the process of designing, developing and verifying a space system as an integrated system able to fulfil the objectives of a mission within acceptable technical and programmatic frames.

The step-by-step design process is guided by considering what the space system seeks to achieve. What orbit will the mission need as a consequence? What kind of instruments and how large a payload? What will be the payload's optimum operating temperature, and how much power will it require? How stable and steerable does the spacecraft platform have to be? What kind of communications infrastructure and associated ground segment will the mission need? Which launcher will be best suited to deliver it into space?

There can be many potential solutions to each question so system engineering is as much an art as a science, with trade-offs made between the different options in terms of performance, risk, cost, reliability and turnaround time, among other factors. The design team includes experts on the various technical disciplines involved to advise on their integration into the overall design.

At the end of these feasibility and preliminary design studies – known as 'Phase A' studies – a baseline space system plan is in existence, defining necessary elements and including initial programmatic estimates. Follow-up 'Phase B' studies turn the preliminary design into a full system design which can then be developed further.

Among the most important factors in deciding whether to proceed to further stage is a mission's likely cost. The process of putting accurate price tag onto space projects is an associated discipline within the Systems Engineering domain called 'Cost Engineering'.  
 
Last update: 9 February 2010