Transcript Hansen 1
Titan Flyby Altitude – Tour Updates Upcoming Observations in 2006 C. J. Hansen 6 January 2005 Background: Safe Titan Flyby Altitude • The atmospheric density experienced by the s/c on the Ta flyby was higher than expected, leading to concerns about low altitude flybys possibly putting the s/c in safe mode – The thrusters fire to overcome torque on the s/c from the atmosphere – If the density is too high the thrusters cannot compensate and the s/c goes off point – If the thrusters fire continuously for >7 sec the s/c enters safe mode • • • The altitude of the T3, T5, and T7 flybys was raised by lowering the altitudes of the T4, T6, and T8 flybys Starting with T16 we won’t have that option because we have long series’ of 950 km flybys – the tour must be re-designed to fly at higher altitudes The AACS team has been working to define the density at which the s/c will lose control – This density is dependent on the orientation of the s/c at closest approach, also on the type of activity (slewing) taking place • TAMWG has been meeting to develop an atmospheric model that predicts density as a function of altitude, given the differing values measured to-date Titan Flybys in 2006-2008 21 low altitude Titan flybys Tit an Flyby 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 H [k m] 1 8 55 1 8 79 1 9 06 950 950 950 950 950 950 1 5 00 950 2 7 26 950 950 950 950 950 950 2 4 26 950 1 9 44 1 3 00 3 2 12 950 950 1 3 00 950 950 950 950 950 1 3 48 V [k m/ s] 5 .8 5 .8 5 .8 6 .0 6 .0 6 .0 6 .0 6 .0 6 .0 5 .9 6 .0 5 .8 6 .3 6 .3 6 .3 6 .3 6 .3 6 .3 6 .1 6 .3 6 .2 6 .2 6 .1 6 .3 6 .3 6 .3 6 .3 6 .3 6 .4 6 .4 6 .4 6 .3 Planned Dat e 4/ 3 0/0 6 5/ 2 0/0 6 7/ 0 2/0 6 7/ 2 2/0 6 9/ 0 7/0 6 9/ 2 3/0 6 1 0 /09/ 0 6 1 0 /25/ 0 6 1 2 /12/ 0 6 1 2 /28/ 0 6 1/ 1 3/0 7 1/ 2 9/0 7 2/ 2 2/0 7 3/ 1 0/0 7 3/ 2 6/0 7 4/ 1 0/0 7 4/ 2 6/0 7 5/ 1 2/0 7 5/ 2 8/0 7 6/ 1 3/0 7 6/ 2 9/0 7 7/ 1 9/0 7 8/ 3 1/0 7 1 0 /02/ 0 7 1 1 /19/ 0 7 1 2 /05/ 0 7 1 2 /20/ 0 7 1/ 0 5/0 8 2/ 2 2/0 8 3/ 2 5/0 8 5/ 1 2/0 8 5/ 2 8/0 8 2006 2007 2008 Safe Titan Flyby Density • Low-altitude Titan flyby are all performed with thrusters. Thrusters are used: – – – – To overcome Titan atmospheric torque To perform target motion compensation (TMC) To slew the S/C about X, Y, Z-axis (or multi-axis) for science observation To maintain a set of commanded per-axis attitude controller dead-band • The safe Titan flyby density is highly scenario dependent. It is a function of many variables: – – – – – – – • Thruster magnitude Spacecraft’s attitude time history Spacecraft’s projected area and c.p. location near TCA Spacecraft’s inertia properties (including c.m.) RCS controller dead-band Per-axis slew rates near TCA Titan-relative S/C flyby velocity AACS team used a test bed named Flight Software Development System (FSDS) to determine the tumbling densities of all low-altitude flybys Reference Trajectory Modifications • The project started development of the new tour in December – Changes won’t be huge – petal rotation, icy satellite flybys, occultations will still happen, but times may move, sometimes considerably • The AACS team has used the current TOST plan to define a safe density for each flyby based on the s/c attitude – If the tour is designed at precisely those altitudes / attitudes we lose some amount of flexibility – any attitude which is not safe at that altitude will not be possible – Discussed at length at TOST November workshop – TOST made recommendations to Project • Altitude decisions made at Project meeting November 30 – Used INMS density multiplied by AACS-driven fudge factor, with cosine latitude dependence – General policy was to be conservative on early inbound Titan flybys, take more risk on later outbound flybys (but thruster torque dropping so these still turn out to be relatively high TOST Input to Process • The correlation of s/c attitude with safe flyby altitude is a concern to TOST planning – A workshop was held 18 Nov. to discuss the impact on TOST plans and flexibility of fixing an altitude and thereby fixing the s/c attitude – One particular outlier was T20 option a • Attitude of the spacecraft at closest approach is predominantly either –Z to Titan, -X to ram (RADAR + INMS) or –Y to Titan, -X to ram (ORS + INMS) • Comparison of T25 and T26 results (see Frautnick presentation) shows that –Y to Titan, -X to ram differs from –Z to Titan, -X to ram by only 5 km – T25 and T26 best for comparison because at ~ same latitude, timeframe TOST “Flexibility” Recommendation • Preserve the capability to switch between ORS + INMS and RADAR + INMS – 5 km difference in altitude – TOST recommends that this be subsumed in overall project margin, not added on top • Preserve the capability to fly either the a or b options of T20 and T32 – Choose the higher altitude, or – Subsume difference in project margin • For some flybys science gain is worth additional risk – MAG, INMS would like to go low to get data deeper in atmosphere (INMS) and search for an internal field (MAG) – On many flybys however outbound science is too important to risk Flyby recommendation summary Implementation: Tour Modifications • Tour redesign is underway – New tour plus limited case studies are out for review – Team review due January 5 – Comments to TWT and OST’s, TWT and OST feedback due January 11 • UVIS is more impacted than any other team because so much of our science comes from occultations – Timing shifts necessitate re-integration of science sequences already on the shelf – Actual occultation geometry may change • Initial response from UVIS was to spend delta-v to maintain timing of old tour – Based on initial NAV analysis of a cost of 35 m/sec – That turned out to be incorrect – cost is > 100 m/sec • New strategy is to emphasize importance of occ’s to the project, try to get commitment to do re-integration Implementation schedule • Feedback on the new reference trajectory will be reviewed at the PSG • New (final) tour developed February 3 – 13 • Modifications begin with T17 (S23), September ’06 • Sequence re-integration will be handled in aftermarket process Upcoming Observations in 2006 Petal Rotation Rev 20 – 25 Summary Titan Flybys • • • • • • • T10 T11 T12 T13 T14 T15 T16 15 January 27 February 18 March 30 April 20 May 2 July 22 July UVIS solar occultation RSS gravity science RSS earth occultation RADAR RSS earth occultation MAPS – unique local time RADAR, UVIS stellar occultation Tour phase: petal rotation to magnetotail In equatorial plane until July Only one relatively close icy satellite flyby (no targeted flybys) Rhea 21 March 82,000 km Backup Charts Safe Density (Phase A) [But without the 5% DKDK margin] Safe = 0.932Tumble Titan Flyby C/A Instrument(s) S/C Orientation 16 17 18 19 20 20 21 23 RADAR INMS, RADAR INMS, RADAR RADAR ORS RADAR INMS, RADAR RADAR -Z to Titan, -X to ram -Z to Titan, -X to ram -Z to Titan, -X to ram -Z to Titan, -X to ram -Y to Titan, +X to pole -Z to Titan, -X to ram -Z to Titan, -X to ram -Z to Titan, -X to ram Tumbling Density [10-10 kg/m3] 40.57 40.66 40.45 35.13 25.30 34.75 34.35 36.45 Safe Density [10-10 kg/m3] 37.81 37.90 37.70 32.74 23.58 32.39 32.02 33.97 Safe Density (Phase B) [1] [But without the 5% DKDK margin] Safe = 0.932Tumble Titan Flyby C/A Instrument(s) S/C Orientation 25 RADAR 26 INMS 27 RSS 28 RADAR 29 RADAR 30 RADAR 32 INMS 32 UVIS/VIMS -Z to Titan, -X to ram -Y to Titan, -X to ram -Z to earth, -Y to ram -Z to Titan, -X to ram -Z to Titan, -X to ram -Z to Titan, -X to ram -Y to Titan, -X to ram -Y to sun, -X to ram Tumbling Density [10-10 kg/m3] 32.70 Safe Density [10-10 kg/m3] 30.48 35.32 32.92 27.06 25.22 32.17 29.98 30.47 28.40 32.37 30.17 34.52 32.17 29.23 27.24 Safe Density (Phase B) [2] [But without the 5% DKDK margin] Safe = 0.932Tumble Titan C/A Flyby Instrument(s) 36 INMS 37 INMS, ORS 39 RADAR 40 INMS 41 RADAR 42 INMS 43 RADAR S/C Orientation -Z to Titan, -X to ram -Y to Titan, -X to ram -Z to Titan, -X to ram -Y to Titan, -X to ram -Z to Titan, -X to ram -Y to Titan, -X to ram -Z to Titan, -X to ram Tumbling Density [10-10 kg/m3] 32.65 Safe Density [10-10 kg/m3] 30.43 32.72 30.50 31.19 29.07 32.22 30.03 31.00 28.89 31.17 29.05 30.45 28.38