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Learn how systems engineering plays a crucial role in translating scientific goals into reality through the development of innovative technologies like the JWST Microshutter Array MLA. Discover how systems engineers facilitate communication between scientists and engineers, ensure technical feasibility, and enhance the overall success of scientific missions.
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JWST Microshutter Array (technology) MLA (planetary) From Science Goals To Reality: The Role of Systems Engineering Carolyn Krebs Associate Director for Science Engineering Code 601 May 3, 2005 WFC3 (Earth- orbiting) IRMOS (ground-based precursor)
How does systems engineering relate to science? • A scientist needs a measurement • Some are primarily interested in the data and less interested in how it is obtained • Others have excellent concepts in mind for obtaining the measurement and data, but they are content to leave the implementation thereof to engineers • Still others are highly engaged in all aspects of the measurement from concept through design and final implementation • The systems engineer serves as a translator to enable all three scenarios
What does translation mean? • With a science instrument-driven mission, it is rare that nice, tidy requirements will be handed to you with a red bow on top • The job probably hasn’t been done before • The measurement will likely push the edge of what is possible • Technology readiness of some elements is often not mature • If a similar measurement has been done before, a new implementation or extension of the heritage can be as challenging as the first time: need to figure out what transfers and innovate where it doesn’t
What does translation mean? (cont’d) • A crucial job of the science systems engineer is to thoroughly understand what the scientist is trying to measure and how • Get involved very early…”glimmer in the eye” stage • Understand the science being performed, how the scientist intends to take the data, how the data will be used, and what the key drivers are • Ask a lot of questions that relate to an eventual implementation • Write the answers down as placeholders for an eventual requirements document/ISAL run • Encourage the scientist to begin defining a Design Reference Mission (DRM) for how the mission and instrument will be operated, as well as the science requirements - will become the touchstones of trade studies and eventual requirements documents
What does translation mean? (cont’d) • As the concept matures, the science systems engineer iterates with the scientist and discipline experts to facilitate and define the possible • Informal trade tree sessions are key • Allocation of the largest margins to the riskiest components from the beginning can save a lot of grief later - start “bottoms up!” • Be prepared to work in a sometimes “unstructured” environment and to accept the translator role of facilitating (not demanding) “chaos” into “order” • Respect that not everyone in the external world works to the standard GSFC processes: find a way to accommodate that, when necessary, that is consistent with the intent of the GSFC processes • Respect that not everyone within GSFC works to the GSFC processes the same way: consider your team and the job, thentailor the approach to be consistent with them and the GSFC processes • Respect that many scientists bring excellent engineering talents to the table: include them in • Don’t forget that an instrument flies on a mission: include them in
What does translation mean? (cont’d) • Trades involve more than pure engineering • Sometimes engineering has to yield to science imperatives (systems engineer facilitates with disciplines) • Sometimes the scientist has to yield to engineering realities (scientist facilitates with science team) • At some point, a proposal wins, and the more traditional systems engineering processes segue in • The science systems engineer is crucial to that transition • Bullets above continue to apply
The role of the new Code 600 Associate Director for Science Engineering function • To provide enabling engineering and technology support to Code 600 for instrument and mission concept development, in partnership with AETD • Performs supervisory and career development function for engineers badged to SED • 100% matrixed to, and co-located with, SED Divisions/Labs/Branches • Coordinates externally matrixed engineering support from AETD • Oversees internal SED engineering processes and practices The engagement of systems engineering is crucial to fulfilling this charter
What is being done to enhance science systems engineering? • The “bullpen” • Early engagement of systems engineering has been posited as crucial to sound concept development • The scientists have also expressed a desire to have much earlier access to systems and discipline engineering skills when developing a concept • The ISAL has expressed a desire for more maturity on entering concepts (pre-pre-ISAL) • A “bullpen” concept, providing ready access to a systems-led team of discipline experts at “first light” of an idea, has been proposed to satisfy these mutually complementary desires • Planned embedding of a systems engineer in each science division
Really stories are better than viewgraphs… • Questions for the panel members: • Tell one story that you think really illustrates the link between science and systems engineering • If you had one word of advice for systems engineers, what would it be?