The FireBird mission - a scientific mission for Earth observation and hot spot detection

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The FireBird mission - a scientific mission for Earth observation and hot spot detection Terzibaschian, Thomas Reile, H., Lorenz, E. DLR, Germany 9th IAA SYMPOSIUM ON SMALL SATELLITES FOR EARTH OBSERVATION, Berlin 2013, Session 02, Missions I

Content 1. BIRD HERITAGE FOR FIREBIRD 2. THE MISSION GOALS 3. THE MISSION POLICY 4. THE MISSION SCHEDULE 5. THE MISSION SEGEMENTS 6. COOPERATION INTERFACES 7. SUMMARY This presentation will introduce the FireBird mission invite for cooperation show the possible cooperation interfaces Slice 2

1 BIRD HERITAGE FOR FIREBIRD (1) BIRD payload with Hot Spot Recognition System BIRD satellite (Flight Model) 60x60x60 cm³, 90 kg PSLV-C3 (India) 22.10.2001 TES (ISRO), PROBA (ESA), BIRD (DLR) SSO 568km circ., i = 97.8 Mission goal: Fire reconnaissance by using a dedicated small satellite Slice 3

1 BIRD HERITAGE FOR FIREBIRD (2) Fire cluster No Eff. fire temp., K Eff. fire area, Ha Front length, km Energy release, MW Front strength, kw/m 1 815 0.48 4 130 30 2 715 2.3 7.5 310 40 3 893 0.59 3 210 70 4 >670 <0.78 5 79 15 5 852 0.92 10 300 30 6 957 1.0 9 530 60 7 >690 <0.51 4 62 15 8 796 0.39 3 96 30 BIRD, Australia, January 5, 2002, table with fire products for each detected fire cluster temperature map of geo coded fire clusters temperatures (left image) Mission accomplished: The BIRD data did permit the computation of fire products + geo coding in a unique quality and accuracy. Slice 4

BIRD HERITAGE FOR FIREBIRD, examples On-ground verification of night-time BIRD fire detection ( 18 January 2003, Ammersee area, Bavaria, Germany) On-ground image of the test fire: Active fire area 2x2 m² Max. temperature = 930-990 K Energy release < 0.17-0.22 MW BIRD image in MIR channel: Estimated fire energy release = 0.11 MW unique quality and accuracy Slice 5

BIRD HERITAGE FOR FIREBIRD, examples BIRD detects coal seam fires in the PR China (6. Feb. 2002, (First detection of these fires and evaluation from space) 0.1 1 1 0 MW BIRDimage of the MIRchannel Fire Energy Release in Mega Watt Coal seams, region Wuda (photos: Sep.2001 within the framework of a MOST-DLR-Cooperation) Slice 6

After the big success of the BIRD mission arose the question: How to continue? BIRD HERITAGE FOR FIREBIRD, BIRD HERITAGE FOR FIREBIRD, 2011 DLR started to design the FireBird Mission Slice 7

The FireBird Mission Fire Bird Mission TET-1 BIROS Scientific 1 DLR Mission 2 for IR remote sensing 3 to investigation of high temperature events contributions to climate change characterization of volcanic activities and forecasts validation of other sensor products investigation of anthropogenic influences on normal temperature phenomena 1) Scientific = Not commercial, not operational 2) DLR mission = All mission segments are controlled by DLR 3) IR remote sensing = primary mission goal FireBird is a DLR R&D project, led by the Institute of Optical Information Systems, Berlin Slice 8

2 THE FireBird MISSION GOALS (1) Primary mission goal: remote sensing of high temperature events The same Hot Spot Recognition System as used by BIRD Generation of fire products on board (BIRD algorithms) Verification of new algorithms normal temperature events multi resolution multi sensor technique (MMT) Extension to a two satellite constellation Slice 9

System parameters VIS (3 CCD lines FPA) 2 IR cameras Bands 500 / 600 / 800nm MWIR: 3,4-4,2 µm; LWIR: 8,5-9,3 µm Focal length 90,9 mm 46,39 mm FOV 19,6 19 Detector CCD- Zeile CdHgTe Arrays cooling Passive, 20 C Stirling, 80-100 K Pixel size 7 µm x 7 µm 30 µm x 30 µm Number of pixels 3x5164 2 x 512 staggered Quantisation 14 bit 14 bit Ground pixel size 42,4 m 2) 356 m 2) GSD 42,4 m 2) 178 m 2) Swath width 211 km 2) 178 km 2) Interface Data LVDS SpaceWire LVDS SpaceWire Data rate max 44 Mbit/s 1) nom 11,2 0,35 Mbit/s (ground resolution of VIS channel increased) Slice 10

2 THE FireBird MISSION GOALS (2) The two satellite constellation: 1. The TET-1 satellite (launched June,2012) Is now used by the On Orbit Verification Mission of the DLR space administration. After one year in space it changes to the FireBird mission of the DLR R&D program directorate space 2. The BIROS satellite (launched expected 2014) Funding from German Government (satellite BUS) and from DLR R&D program directorate space. TET-1: 60x60x80 cm³, 120 kg, 500 km SSO BIROS: 60x60x80 cm³, 140 kg, 500..600 km SSO Slice 11

2 THE FireBird MISSION GOALS (3) The BIROS satellite gives the opportunity for working on secondary mission goals 1. Optical navigation experiment AVANTI PicoSat launch from BIROS The PicoSat serves as non cooperative target for optical navigation and proximity operations (100m 10 km distance) Inter satellite link PicoSat BIROS permits the usage of the PicoSat GPS receiver as a BIROS remote device for AVANTI verification Relation to primary mission goal: Experiences for a cooperative behavior of different small satellites in future in fulfilling a common task for future mission concepts Slice 12

2 THE FireBird MISSION GOALS (4) The BIROS satellite gives the opportunity for working on secondary mission goals 2. On Board Mission Planning experiment VAMOS 1. Special SW in the on the BIROS payload computer 2. A special shadow command list in the BIROS board computer 3. Alternative on board scenarios depending on conditions like Memory usage Battery level Clouds over the target areas Detection of fires in the target region (yes/no) 4. Autonomous decision on board about the mission scenario Relation to primary mission goal: Increased efficiency of an Earth Observation mission by maximizing the usage of on board resources Slice 13

2 THE FireBird MISSION GOALS (5) The BIROS satellite gives the opportunity for working on secondary mission goals 3. Optical communication experiment OSIRIS 3 different laser systems for communication to ground data rate up to 1 Gbit/s four quadrant laser detector on board for increased pointing accuracy a beacon laser from ground to satellite supports the BIROS attitude control and can be used for an optical data uplink Relation to primary mission goal: Dramatic extension of downlink capacity comparing it with the standard S-band transmitter of BIROS Slice 14

2 THE FireBird MISSION GOALS (6) The BIROS satellite gives the opportunity for working on secondary mission goals 4. High Agility Experiment HTW 3 special high torque wheels Slew rate up 3 deg/s Different acceleration profiles Verification of several satellite slew profiles Study of interaction with normal attitude control Relation to primary mission goal: Multiple image stripes over one target area Fast switching between different targets Fast re orientation to Sun (more power) Slice 15

3 THE MISSION POLICY 1. FireBird is a DLR mission all mission segments are controlled by DLR R&D the mission is organized as a DLR R&D project 2. FireBird is a science mission The mission is not focused on commercial aspects The mission is not operational The mission is steered by an Principal Investigator and an international, open science team The mission is open for other EO topics 3. FireBird is an IR mission for remote sensing of high temperature events this is the main goal of the mission but secondary goals are accepted and desired Slice 16

4 THE MISSION SCHEDULE BiROS TET-1 Implementation phase Operational phase I Operational phase II Mission KO TET-1 launch as part of The OOV mission TET-1 becomes part of the FireBird mission BIROS launch constellation with TET-1 Project ends Mission? July 2011 ( 2012 June 20 2013 2014 Dec 2015 Slice 17

4 THE MISSION SCHEDULE TET-1 is in orbit since June 2013 (perfect launch from Baikonur) The picture shows the control room teams during LEOP. BIROS STM is close to final Vibration tests (right picture) Slice 18

5 THE MISSION SEGEMENTS The segments and its elements ground segment space segment {TET-1, BiROS } mission operation & control{ Contr. Center, Ground Stations} German Space Operations Center data { ground stations, archive, processing} German Remote-sensing Data Centre launch segment {Launch provider, Launch vehicle, Launch pad, Launch orbit} TBD user segment == Science Segment { Principal Investigator, Science Team } Slice 19

The two circles above Europe show the area covered by the DFD antenna (Neustrelitz) and Weilheim (GSOC) the scheduled default antennas for FireBird. Slice 20

Launch segment: desired BIROS orbit &launch date piggy back launch 500 (best) 600 km circular, SSO Ascending node 10:00.. 13:30 (best case) date: mid end of 2014 Slice 21

6 COOPERATION INTERFACES Reasons for cooperation : improve the scientific relevance of the mission results overcome the bottle neck : download capacity Fire is a global topic Interfaces for cooperation in all mission segments Slice 22

6 COOPERATION INTERFACES User segment: the science team especially for fire topics The DLR Earth Observation Center interfaces for data access Ground segment: Receiving stations, exchange downlink opportunity EO data uplink stations, exchange EO data Space segment: Other EO missions with relevant sensors Cross validation / calibrations Other satellites become part of the mission Common definition of sensors Common decision about orbits Common usage of the ground segment Increase operability launch segment: Launch opportunity EO data, taking part in the FireBird mission Slice 23

7 SUMMARY The FireBird mission is an exciting small satellite EO mission It is a repetition and remarkable extension of the BIRD mission On board generation of fire products Satellite constellation It is the next step towards an operable global fire monitoring, based on small satellite The secondary BIROS payloads prepare next steps High speed data downlink for small satellites High agility extends the EO abilities Proximity operations prepare new mission concepts Small satellites can launch pico satellites Extended on board autonomy up to a variable mission planning The FireBird mission is looking for cooperation Slice 24

THANK YOU FOR THE ATTENTION Points of contact: Program director space hubert.reile@dlr.de Project leader FireBird Principal Investigator FireBird Earth Observation Center (Science Coordinator) Project leader BIROS thomas.terzibaschian@dlr.de eckehard.lorenz@dlr.de doris.klein@dlr.de winfried.halle@dlr.de Slice 25

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