Lessons learned in extended-extended Spitzer Space Telescope operations

The Spitzer Space Telescope is executing the ninth year of extended operations beyond its 5.5-year prime mission. The project anticipated a maximum extended mission of about four years when the first mission extension was proposed. The robustness of the observatory hardware and the creativity of the project engineers and scientists in overcoming hurdles to operations has enabled a substantially longer mission lifetime. This has led to more challenges with an aging groundsystem due to resource reductions and decisions made early in the extended mission based on a shorter planned lifetime. We provide an overview of the extended mission phases, challenges met in maintaining and enhancing the science productivity, and what we would have done differently if the extended mission was planned from the start to be nearly twice as long as the prime mission

Lessons learned in extended-extended Spitzer Space Telescope operations

The Spitzer Space Telescope is executing the ninth year of extended operations beyond its 5.5-year prime mission. The project anticipated a maximum extended mission of about four years when the first mission extension was proposed. The robustness of the observatory hardware and the creativity of the project engineers and scientists in overcoming hurdles to operations has enabled a substantially longer mission lifetime. This has led to more challenges with an aging groundsystem due to resource reductions and decisions made early in the extended mission based on a shorter planned lifetime. We provide an overview of the extended mission phases, challenges met in maintaining and enhancing the science productivity, and what we would have done differently if the extended mission was planned from the start to be nearly twice as long as the prime mission

Spitzer Observatory Operations -- Increasing Efficiency in Mission Operations

This paper explores the how's and why's of the Spitzer Mission Operations System's (MOS) success, efficiency, and affordability in comparison to other observatory-class missions. MOS exploits today's flight, ground, and operations capabilities, embraces automation, and balances both risk and cost. With operational efficiency as the primary goal, MOS maintains a strong control process by translating lessons learned into efficiency improvements, thereby enabling the MOS processes, teams, and procedures to rapidly evolve from concept (through thorough validation) into in-flight implementation. Operational teaming, planning, and execution are designed to enable re-use. Mission changes, unforeseen events, and continuous improvement have often times forced us to learn to fly anew. Collaborative spacecraft operations and remote science and instrument teams have become well integrated, and worked together to improve and optimize each human, machine, and software-system element

Spitzer Space Telescope: Innovations and Optimizations in the Extended Mission Era

NASA’s Spitzer Space Telescope continues to operate well past its original cryogenic mission concept (2003-2009), executing both a follow-on “Warm” mission (2009-2016) and the current “Beyond” (2016-present) mission phase. As Spitzer’s unique Earth-trailing orbit carries it ever further from us (now surpassing 1.6 astronomical unit), its orbital geometry provides challenges to all operational teams. Nevertheless, the combined efforts of the geographically dispersed Spitzer teams ensure that the observatory’s instrumental and observational capabilities remain either undiminished or improved, and the high overall science data collection efficiency remains nearly unchanged. In this contribution, we outline several operational changes, innovations, and optimizations that have both minimized the impact of the growing distance on data transmission and enhanced the precision of data acquired by the science instruments. Though faced with diminishing budgetary resources that reduced staffing and allowed fewer upgrades of aging equipment, extended mission operations can provide an opportunity to acquire extensive science at bargain prices. The spacecraft, ground, and mission operations systems and procedures to perform the extended mission are already in place from the prime mission. The key to maintaining successful extended operations is the proper automation, modification and process enhancement of extant prime mission capabilities and procedures to maximize science return with acceptable risk as opposed to the creation of new capabilities. Spitzer’s successful optimization of existing operational capabilities and the associated lessons learned that have gone into maximizing the lifetime well into its second decade of operation will hopefully provide guidelines for future missions, as it continues to make important contributions to the field of astrophysics, including the recent, highly significant discovery and characterization of exoplanets in the TRAPPIST-1 system

Spitzer Space Telescope: Innovations and Optimizations in the Extended Mission Era

NASA’s Spitzer Space Telescope continues to operate well past its original cryogenic mission concept (2003-2009), executing both a follow-on “Warm” mission (2009-2016) and the current “Beyond” (2016-present) mission phase. As Spitzer’s unique Earth-trailing orbit carries it ever further from us (now surpassing 1.6 astronomical unit), its orbital geometry provides challenges to all operational teams. Nevertheless, the combined efforts of the geographically dispersed Spitzer teams ensure that the observatory’s instrumental and observational capabilities remain either undiminished or improved, and the high overall science data collection efficiency remains nearly unchanged. In this contribution, we outline several operational changes, innovations, and optimizations that have both minimized the impact of the growing distance on data transmission and enhanced the precision of data acquired by the science instruments. Though faced with diminishing budgetary resources that reduced staffing and allowed fewer upgrades of aging equipment, extended mission operations can provide an opportunity to acquire extensive science at bargain prices. The spacecraft, ground, and mission operations systems and procedures to perform the extended mission are already in place from the prime mission. The key to maintaining successful extended operations is the proper automation, modification and process enhancement of extant prime mission capabilities and procedures to maximize science return with acceptable risk as opposed to the creation of new capabilities. Spitzer’s successful optimization of existing operational capabilities and the associated lessons learned that have gone into maximizing the lifetime well into its second decade of operation will hopefully provide guidelines for future missions, as it continues to make important contributions to the field of astrophysics, including the recent, highly significant discovery and characterization of exoplanets in the TRAPPIST-1 system