Developing Mission Trade Space

1. Developing Mission Trade Space Mark Schoeberl Richard Wesenberg Lisa Callahan GSFC

2. Purpose • Given the large number of potential instruments and costing assumptions, we need to do a 0th order analysis on mission configurations – what is optimal, how do costs vary? With this information, we can zero in on the most probable mission configurations to do detailed mission concept studies.

3. Boundary Conditions • Accuracy of input data • Costing information for many proposed instruments is incomplete • HQ constraints on ACE costing is unknown • Instrument sizes and masses are uncertain as are TRL levels in some cases • Number of configurations • There are a large number of configurations given up to four vehicles. However most of these scenarios can be immediately dismissed and this analysis will focus only on the high probability scenarios – 12 of them • Launch vehicles • We are considering Pegasus (small faring), Tarus II (roughly a Delta II) and Minotaur. Faring size is acceptable provided we do not have to fit the MBL - so the MBL has not been considered. • Orbit • Lower orbit (450 km) means more fuel and thus a heavier payload. Assume station keeping with Earth Care • Added ATMS to provide temperature profiling (nearly free) • Mission Science Value (adjustable) • TRL level 6 instruments A-Train are given a score of 1 with enhancements a score of 1.5 e.g Cloudsat radar =1 dual frequency Doppler radar = 1.5 • µ-wave radiometers given a score of 0.5 • IR cloud instrument and ATMS given a score of 0.2

4. Instruments and Science Scores

5. Some Scenarios • Single Bus Mission • Everything can fit but the budget envelope will be steep, mission integration and management will be complicated and expensive • Range $1.2-1.8 B, low end has base instruments only. JPL study showed lower numbers but bus, contingency and run out costs were not completed by JPL from what we can tell. • Two Bus Mission • Similar budget range to single platform with added LV cost. Unless the launch is simultaneous, budget might get spread over a few years which is good. Management is less complex, GSFC does one bus, JPL the other – spreads the work around. • Three Bus Mission • ORCA first then launch the rest… details later

6. Costing so Far Triple bus options CPR+, MSPI, IR, ATMS, SIRICE, GMI Caliop, CPR, MSPI, ORCA, IR, ATMS HSRL, CPR+, MSPI, ORCA Caliop, CPR+, MSPI, ORCA No Payload (bus +rocket +ground system) MSPI +CPR+

7. A Strategy for ACE • Consider ACE to be a program • Fly ORCA & Polder-A (and APS?) behind EC in 2015 then assemble the rest of the E-Train later (Cost ~300-350M) • EC is a good mission but lacks the polarimeter and multi-channel broad swath imager • EC + Polarimeter provides enough information for ORCA retrievals • Fly the rest of ACE in 2020-5 replacing parts of EC – bonus: if ORCA fails you have time to fly a second copy • Advantages • Gets our foot in the door – early ACE data to community • Continues the A-Train time series – allows for some overlap with AT • Ocean color data sooner • Shows strong international partnership • Disadvantages • Would increase total mission cost somewhat • Not strictly Decadal survey

8. Summary • The only way to get under $1.2B (without International Partners) is to drastically descope the mission payload. Even at 1.2B the mission payload is not significantly improved over AT. • $1.6 B mission is a really, really good science mission • Multiple platform solutions stretch out the budget envelope, simplify the systems engineering but will increase cost due to extra buses and LVs. • A scenario where ORCA+Polarimeter launches first and flies behind EC* might have the advantages of getting our foot in the door. • Next steps: • Need better cost number for HSRL, CPR+ • Need guidance from HQ on budget profiles • Need to pick a couple candidates to do a more comprehensive study • Should we explore the EC+ORCA early scenario? *Similar to the OCEaNS mission concept

9. Polder-A summary Type: Passive multi-angle imaging photopolarimeter Instrument concept:Wide field of view telecentric optics (separate for VIS and SWIR), rotating wheel with spectral and polarization filters, and 2-D detector arrays in the focal plane of the optics Directionality: 15 views of a scene, ±55° from nadir Cross-track swath: ±55° Approx. dimensions: 40 x 52 x 36 cm Mass/power/data rate:30 kg / 30 W / 3 Mbps Measurement range: 443–2130 nm Measurement specifics: 2 visible (443, 490 nm), 2 near-IR (670, 865 nm), and 3 short-wave IR (1370, 1650, 2130 nm) bands; three Stokes parameters (I, Q, and U) in all channels except intensity-only channels 1 and 5. A UV band can be added. Ground resolution at nadir: 3 km SNR requirement:200