Chandrayaan1-TIFR

Chandrayaan-1 Mission Colloquium at TIFR, Mumbai August 17, 2007 K Thyagarajan Prog. Dir, IRS/SSS ISRO Satellite Centre

When the media asked former chairman, ISRO

whether India can afford to send a craft to the Moon, he replied

“Can India afford not to go the Moon�

Outline of presentation 

Why go to the Moon?



What’s known about Moon?



Chandrayaan-1 Mission objectives



Payloads in the Mission



Spacecraft configuration



Launch vehicle



Mission profile



Imaging strategy for lunar coverage



Deep Space Network (DSN)



Indian Space science data Center (ISSDC)

Why go to the Moon 

The origin of Moon is still not clearly understood and there have been several speculations



Space programme for Lunar exploration was undertaken as early as 1959.



Several Lunar exploratory missions since then have been conducted



Interest in Lunar science was renewed when imaging systems onboard NASA’s “Galileo” spacecraft sent picture of the previously unexplored regions of the Moon during 1990



Galileo identified a large impact basin, about 2500km in diameter and 10 to 12 km deep in the south pole Aitken Region on the far side of the Moon

Why go to the Moon (Contd ..) 

With the development of new technology, a new era of lunar exploration by many countries have now begun using advanced instruments and microelectronics



Apart from scientific interest, the Moon could have economic benefits to mankind and could be of strategic importance





The Moon’s surface has about one million tonnes of Helium-3



Moon contains 10 times more energy in Helium-3 than all the fossil fuels on Earth



Helium-3 is believed to be fuel of the future

Outpost for further planetary explorations and possible human settlements

What is known about Moon? Landing and Sample Return Missions A-13

Apollo 11-17 (13),

Luna 16, 20, 24 (1969-74) Orbiting Missions Clementine (1994) UVVIS, NIR, LWIR, LIDAR Mineral Mapping Lunar Prospector (1998) -ray, , Neutron Spectrometers, Magnetometer, Electron Reflectometer, Doppler Gravity Chemical Mapping, Water (?) SMART-1(2003) Mapping of geological and mineralogical resources (Res: 40m)

A-15 L-24 A-17 L20 A-11

A-14

L-16

A-12 A-16

Future Lunar missions 

Chang’e-1 by China scheduled for late 2007 



Selene by Japan scheduled for late 2007 



Moon’s Topography, mineral content and gravity

LRO by USA scheduled in late 2008 



3D map of Moon, Moon’s Soil composition & mineral distribution

Water-ice at poles, selection of soft-landing sites, etc

Russian Mission Scheduled for 2009

Understanding the origin and Evolution of the Moon The bulk chemistry of Moon

Physical Properties of the Moon

Topography

Nature of the Lunar Crust

Gravity Magnetic Field

The Lunar Far-side: Rock types, Chemistry

Radiation Environment

Special Regions of Interest: Polar Regions ,

South Pole Aitken Region, Selected Basins and Craters with central uplift

Water on Moon?

Objectives of the Chandrayaan-1 Mission 

Simultaneous Mineralogical, Chemical & Photo-geological Mapping at resolutions better than previous and currently planned Lunar missions



High resolution VIS-NIR mapping of the lunar surface to identify Fe, Al, Mg, Ti bearing mineral with high spatial resolution (100m)



3D mapping of lunar surface at very high spatial resolution (~5 m)



High Resolution Laser ranging for topographical Map of the Moon (~0.1 deg longitudinal separation grids)



Create Expertise & Motivate the Young Minds in Space and Planetary Science

Chandrayaan-1 Mission Configuration : 100 km polar orbiter Observation Period : 2 years

Hyper Spectral Imager (HySI) (0.4-0.9µm) Terrain Mapping Camera (TMC)(0.5-0.75 µm)

Lunar Laser Ranging Instrument (LLRI) Low energy X-ray spectrometer (LEX) (1-10KeV) High energy X- ray spectrometer (HEX) (10-200KeV)

A new era of International Cooperation Based on science objectives and spacecraft resources, several AO proposals were accepted; they will complement/add to the Indian experiments to meet the basic science goals of the mission.

I. IR spectrometers for mineral mapping (SIR-2 and MMM) II. An experiment to detect neutral atoms (SARA) III. An experiment to search for water-ice at the poles (mini-SAR) IV. An experiment to monitor energetic particle environment (RADOM)

Lunar environment - Thermal 

Sun movement restricted to 1.50 w.r.t lunar equator



Eternal lights at polar high land regions

 Low temperature excursions (-150 C to –500 C)  Presence of water nearby likely  Continuous solar power generation possible

Lunar environment - Other 

South Pole Atkin Region (SPAR), largest impact basin in Solar System extends from South pole to 400 S latitude on the far side



No known Seismic activity, no surface winds



Hard shadows, no atmospheric dispersion



Crystalline lunar soil can be paved glassy using microwaves, roads, craters to parabolic antenna backplanes

Comparison of Moon’s & Earth’s Orbit Moon

Earth

Semi-major axis

384.4 x 103 km

1.000 AU

Revolution period

27.32 days

365.26 days

Orbit inclination

18.3° to 29° w.r.t Earth’s equator

0.00 w.r.t ecliptic plane

Eccentricity

0.055

0.017

Obliquity

6.7°

23.4°

Rotation period

27.32 days

23 h 56 min

Radius

1738 km

6378 km

Mass

7.35 x 1022 kg

5.98 x 1024 kg

Mean density

3340 kg/m3

5520 kg/m3

Escape velocity at surface

2.38 km/s

11.2 km/s

Main Characteristics of Moon’s Orbit 

The moon is a satellite of earth in a slightly elliptical orbit, inclination w.r.t the earth equator oscillating between 28035’ and 18021’ with a period of 18.6 years.



The angle between lunar equator and ecliptic plane is approximately 1.50 resulting in poor illumination of polar regions



No Atmospheric Drag



No SELENO-Magnetic Fields



100 Km Circular Polar Orbit (Period of 118 min.) selected to meet the Imaging requirements

CHANDRAYAAN-1 ORBIT • Altitude: 100km • Inclination: 90° • Period: 117.6 min • Mean ground velocity: 1.54 km/s • Earth as seen by Moon: 1.9° - 2.1°

• Beam width of 0.7 m X-band antenna: 3.6° • Moon disc at satellite: ±70°

SL.NO .

1

PAYLOAD

TMC

Spectral band 0.5 to 0.85μm

Sensor Config Three Stero

Objective

Topography

Cameras

2

HySI-VINR

0.4 to 0.92μm

Wedge filter Mineral mapping

3

LLRI

1064nm, 10mJ

4

HEX

20 – 250 keV

5

IMPACTOR

--------------

6

CIXS (LEX)

0.5 to 10keV

7

Mini-SAR

2.5GHz

Detection of poalr ice

8

SIR-2

0.93 to 2.

Mineral Mapping

9

SARA

10eV to 2keV

Mass spectrometer

10

RADOM

>8Kev

Si Semiconductor Radiation monitor

11

MMM

0.4-3.0μm

Topography &Gravity CdZnTe Detector

Chemical mapping Technology Demo

Swept Charge Chemical mapping CCD

Atmospheric neutrals& magnetic anomaly

Mineral Mapping

Payloads 



Payloads from ISRO  Terrain Mapping Camera with front, nadir and aft views(TMC).  Hyper Spectral Imager(HySI).  Lunar Laser Ranging Instrument (LLRI).  High Energy X-ray payload(HEX).  Moon Impact Probe (MIP) Payloads from international agencies  Low Energy X-ray (LEX)payload (CIXS). From Rutherford Appleton Laboratory (RAL),UK / ESA  Mini SAR from Applied Physics Laboratory (APL), USA under an MOU with NASA  SIR-2 from Max Plank Institute, Germany under an MOU with ESA  Radiation Dose Monitor from Bulgarian Academy of Sciences  Sub-keV Atom Reflecting Analyser (SARA) Experiment developed jointly by IRF Sweden, SPL-VSCC India, ISAS/JAXA Japan and VBE Switzerland under an MOU with ESA  Moon Mineralogy Mapper (M3) from JPL, US., under an MOU with NASA

Terrain Mapping Camera (TMC) 

Stereoscopic imaging instrument in panchromatic spectral band for generating high resolution three dimensional map of Moon



Consists of fore, nadir and aft detectors housed in single enclosure



Spatial: Swath – 20km, Resolution – 5m



Spectral: 0.5 to 0.85µm



4000 pixel, 7µ linear APS detector

Hyper Spectral Imager (HySI) 

In visible and near infra-red band



Spatial: Swath – 20km, Resolution – 80m



Spectral: 0.4 to 0.95µm, resolution better than 15nm



256 x 512 pixel, 50µ area APS detector

Lunar Laser Ranging Instrument (LLRI) 

Objectives 

To determine the global topographical field of Moon using the laser altimetry data



To determine an improved model of the lunar gravity field



To supplement TMC and HySI payloads



Laser wavelength: 1064 nm



Laser energy: 10 mj



Vertical Resoultion: < 5m



Detector: Avalanche Photodiode



First time coverage of polar regions of Moon

High Energy X-ray Spectrometer (HEX) 

Objectives 

Identify degassing fault zones by mapping of 222Rn and its radioactive daughter 210Pb, helps understanding volatile transport on Moon



To determine the surface composition of Pb-210 in the uranium decay series by it’s 46.5 keV gamma ray



To determine the integral flux of gamma rays coming out of Moon in the region 10 – 250 keV



Energy Resolution: <7% @ 60 keV



Energy range: 20 – 250 keV



Spatial resolution: 20 km



Swath: 40 km x 40 km



Detector: CdZnTe (CZT)

Moon Impact Probe (MIP) 





Objectives 

Scientific exploration of the Moon near range



To design, develop and demonstrate technologies required for impacting a probe at the desired location on the Moon



Qualify some of the techniques required for soft-landing missions

Payloads 

Mass spectrometer to assess the lunar atmosphere



Radar altimeter to measure the altitude with a resolution of 5m



Video imaging system (VIS) to take photographs of Moon’s surface

From 100km orbit, it takes ~18 minutes to hit the Moon surface

Low Energy X-ray Spectrometer (LEX) 

Updated version of Smart-1 payload



Consists of two instruments 

Chandrayaan-1 Compact Imaging X-ray Spectrometer (C1XS) 



Main instrument

X-ray Solar Monitor (XSM) 

Provides incident solar flux as input to C1X



Objective: To carry-out high quality X-ray spectroscopic mapping of the Moon in order to study elemental abundance of Moon



Basically measures fluorescent emissions from the surface of Moon and also monitors incident Solar X-ray emissions



Detects Mg, Al, Fe and Si during non-Solar flare conditions (C1X)



Detects Ca, Ti during Solar flare conditions (XSM)



Energy range: 0.5 to 10 keV

Miniature Synthetic Aperture Radar(Mini-SAR) 

Objective 

To map polar regions at an incident angle of app. 37 deg. Basically looks for ice / water deposits



To resolve discrepancy in the data available from Clementine, Lunar Prospector and Arecibo Radar satellites with respect to nature and amount of deposits in the lunar polar region



Range swath: 44km, Azimuth swath: 8km



Ground range resolution: 140m for altimeter



Radar system can operate as altimeter / scatterometer, radiometer and as a synthetic aperture radar

Smart Infra Red Spectrometer (SIR-2) 

Updated version of SMART-1 payload



It is a highly compact and near infra-red spectrometer



Objective 

Analyze the lunar surface in various geological / mineralogical / topographical units



Study of vertical distribution of crystal material



Investigate the process of crater, maria and basin formation on Moon



Explore “Space Weathering” process of the lunar surface



Search for ices at the lunar poles



SIR-2 collects the Sun’s light reflected by the Moon



Spectral Wavelength: 0.93 to 24 µm



Spectral resolution: 6nm

Sub keV Atom Reflecting Analyzer (SARA) 



Consists of two payloads 

Chandrayaan Energetic Neutral Analyzer (CENA)



Solar Wind Monitor (SWIM)

Objective 

Imaging of the surface magnetic anomalies (Moon doesn’t have magnetic core, like in Earth. But Moon has different magnetic fields at different surface areas which is an anomaly)



Studies of space weathering, i.e., physical and chemical changes that occur to the exposed materials on the surface of the Moon



Imaging of Moon’s surface composition including imaging of permanently shadowed areas and search for volatile rich areas

Radiation Dose Monitor (RADOM) 

Updated version of similar instrument flown in MIR space station since 1988



Objective 

Measure the particle flux, deposited energy spectrum, accumulated absorbed dose rate in the lunar orbit and evaluate the contribution of protons, neutron, electrons, gamma rays and energetic galactic cosmic radiation nuclei



Provide an estimation of the dose map around Moon at different altitudes



To evaluate the shielding characteristics (if any exists) of the Moon near environment towards galactic and solar cosmic radiation and solar particle events



The experiment will be useful for future manned missions

Moon Mineralogy Mapper (M3) 

Payload is solar reflected energy imaging spectrometer



Objective 

To assess the mineral resources of the Moon



To characterize and map the composition of the surface at high spatial resolution



Spectral- Range: 0.7 – 3.0 µm, Resolution: 10nm



Radiometric: Range 0 to max. Lambertian, Sampling 12 bits



Spatial: Swath 40km, Resolution 30m

SWIM

XSM

MIP RADOM

SIR-2 LLRI

CENA

CIXS

MiniSAR

TMC

M3

HEX HySI

Spacecraft Configuration 

S-band transmission through omni antenna 

 

 

 

Configured with two 90 hemi-spherical coverage antennas with opposite polarisation placed on the diametrically opposite face in the S/C

X-band transmission through Steerable Dual Gimbal Antenna Sensors – CASS, SPSS, Star sensor BMU handles Command, Telemetry, AOCS functions Bi propellant system for orbit raising & maintainence CCSDS – compatible with world-wide network & DSN Single bus / battery system  

Canted Solar panel generates 700 W on normal incidence 27 AH Li Ion battery

PLATFORM SPECIFICATIONS (NORMAL MODE POINTING AND STABILITY)

Axis

Attitude Pointing

Rate

Yaw

0.05

3.0E-4 /s

Roll

0.05

3.0E-4 /s

Pitch

0.05

3.0E-4 /s

Post-facto attitude determination: 40 arc-sec for entire mission life

X-Band Downlinks from Chandrayaan-1 VIRTUAL CHANNEL - 0

1. 2. 3. 4.

TMC – APS1 TMC – APS2 TMC – APS3 HySI

SSR #1

VIRTUAL CHANNEL - 1 miniSAR VIRTUAL CHANNEL - 3

1. MIP 2. C1XS 3. HEX 4. SIR-2 5. LLRI 6. SARA 7. RADOM 8. S-LBT 9. GYRO 10.STAR SENSOR

SSR #2

Channel coder

SSR #3

VIRTUAL CHANNEL - 2 M3

X-band link

Mass Budget Bus Elements (kg)

Payload (kg) S/C Dry Mass (kg)

Growth Margin (kg)

405.0

89.0 494.0

9.0

Dry Mass (kg)

503.0

Propellant (kg)

797.5

Pressurant (kg)

Lift off Mass (kg)

3.5

1304.0

Power Budget Sub-system

HEX, LLRI, AO

Sunlit (W)

44

Eclipse (W)

44

IMAGING (Average) + CIXS 34(6+28)

0

DATA Tx

0

44

BUS

236

228

TOTAL

534

316

INT. LOSS (4%)

22

13

REQUIREMENT

556

329

GENERATION

607

27AH@ 25% DOD

MARGIN

51

DSN-18

Chandrayaan-1 Ground Segment ISTRAC IDSN STATIONS – S BAND DSN-18 S/X (ALL Phases)

DSN-32 S/X (> 1 Lakh km)

Ant. Dia (m)

18.3

32

G/T (dB/K)

30.6

37.5

G/T looking at Moon (dB/K)

26.0

32.0

79

94/84

10(Az) /1(El) 5/ 0.5

0.4 0.01

20

20

0.05

0.05

-

0.3mm rms

Specifications

EIRP (dBW)

Antenna rates Velocity (deg/s) Accln. deg/s*2 Tone Ranging Accuracy (m) Range-rate Accuracy (m/s)

Surface finishing (wrt parabola)

Polar Satellite Launch Vehicle (PSLV)

Basic Capabilities

SSPO ( 725*725 km, i= 98.370 )

1250 kg

LEO (300*300 km )

3400 kg

GTO (240 * 36000 km, METSAT) 1050 kg Chandrayaan-1 (260 X 24000 km) 1304 kg

Vehicle Configuration (6S9+S139)+L40+S7+L2.5

Indian Lunar Mission Sun

GTO

ETO

Trans Lunar Injection Lunar Insertion Manoeuvre Mid Course Correction

Lunar Transfer Trajectory

To achieve 100 x 100 km Lunar Polar Orbit. PSLV to inject 1304 kg in GTO of 260 x 24000 km. Lunar Orbital mass of 623 kg with 2 year life time.

Initial Orbit ~ 1000 km Final Orbit 100 km Polar

Moon at Launch

Launch Window 

It is necessary to have a LOI manoeuvre when Moon is at equator, i.e., when Moon is in the ascending or the descending node.



Two launch opportunities in 28 days (lunar cycle) are possible.



Capture at descending node is not favourable in all seasons as Sun lies in the perigee side, causing long shadows near apogee.



Maximum shadow allowed per orbit is 100 minutes

Transfer phase to lunar capture CAP08AP09-NOM-00

350

70

Altitude = 511.063963km Geodetic latitude -4.250270° East Longitude 138.301821°

300

60

Velocity 9.707127° Flight Path Angle 80.292873° Velocity Azimuth 107.439542°

250

200

50

40

Orbit Size: 260km x 24075km Inclination = 17.93742° Arg Perigee = 169.06269°

150

30

100

20

50

10

0 0

50

100

150

Time in hrs elapsed since injection (Launch Apr 09, 2008)

200

0 250

Thousands

80

Injection parameters - version #1

Radial distance from Moon (km)

Radial distance from Earth (km)

Thousands

SOI index 11032

400

Consolidated Network Stations S.N 1.

2.

3.

Mission Phase

Stations

Short Range Support (Perigee arc coverage) – S-band support During Spacecraft separation

Biak, Hawaii

During burn #1 (TM)

TT, Kourou, Natal

During burn #2 & #3 (TM)

Port Blair, Brunei, Biak

LEOP phase (upto 1 lakh km) S-band support (TC, TM, TRK)

Bangalore, Biak, MaryLand (APL), Mauritius, Hawaii, Lucknow, Bearslake

X-band support

Bangalore, Mauritius (post Hawaii (post LEB #2 & #3)

LEB

#1),

DSN support LEOP phase

Bangalore, Bearslake, Goldstone

APL,

Normal phase

Bangalore, Bearslake, APL, JPL -Goldstone (on requirement)

JPL-

Inertially fixed lunar polar orbit 



Orbit regression is negligible.  Lunar sun synchronous orbit not possible. Inertially fixed polar orbit experiences continuously varying sun illumination over a year.

Lunar Orbit as seen from Earth M

M

Face on T

Edge on T+7 days

Face on T+14 days

Classification of Payloads 

Illumination dependant    



Illumination independent    



TMC + HySI M3 SIR-2 C1XS LLRI MiniSAR SARA HEX

Moon independent  



RADOM XSM of C1XS SWIM of SARA

Sun aspect variations in a year

300 300

4 Months M 300 4 Months 300

Prime zone

Polar region

Imaging Strategy - Definitions 

Prime Imaging season Season in which the solar aspect angle at lunar equator is within ±45°. Season comprises of 90 days centered around noon/midnight orbit suitable for optical imaging.



Prime Imaging Zone Region within ±60° latitude of lunar equator, sensitive to illumination variation resulting from sun movement over the season. This zone is covered by imaging payloads within 60 days centered on noon/midnight orbit restricting the solar aspect angle within ±30° with respect to the lunar equator.



Polar zone High latitude zones (beyond 60°) which are poorly illuminated and insensitive to sun movement. Low lands are permanently shadowed, high lands are perpetually under grazing sun rays. Imaging coverage is for 15 days wherein the solar aspect angle is restricted in the bands of ±30° and ±45° respectively.

Imaging Strategy – Definitions … 

Secondary Imaging season Season in which the solar aspect angle at lunar equator is beyond ±45°. Season comprises of 90 days centered on dawn/dusk orbit. In this period, payloads which are not dependent on ground illumination levels like mini-SAR, HEX, LEX, LLRI, SARA and RADOM are operated.



Imaging Cycle All Sunlit longitudes of Moon are swept once in 28 days owing to rotation about its own axis termed as an Imaging Cycle. Each imaging season has TWO cycles.

DSN Visibility at 100 km orbit

Complete Lunar Surface Coverage DSN support for payload data transmission

Bangalore + APL-USA

Area covered in prime imaging zone

60º N to 60º S

Area covered in polar imaging zone

90°N to 60°N, 90°S to 60°S

Latitude zone covered in one visible orbit

60°

No: of orbits visible / day

10

Time required to visit all longitudes

2 prime image seasons

Time available for each prime imaging season

3 months

Time available for each secondary imaging season

3 months

Number of prime imaging seasons

3

Number of secondary imaging seasons

2

Minimum time required to cover entire lunar surface

15 months

Distinct Mission Features 

Features that affect payload data processing  

  



Spacecraft yaw rotation Imaging in ascending and descending paths Varying Illumination conditions Vernier ground track shifts Variation in altitude

Features that affect downlink  

Sun outage Rain attenuation during Moon rise / Moon set

Worst Case Eclipse – Earth & Moon Shadow PENUMBRA

M

48 m M.S

M.S – Moon shadow,

UMBRA

72 m P.E.S

48 m M.S

48 m P.E.S

37 m E.S

P.E.S – Part Earth Shadow,

35 m 72 m 48 m 13 m M.S P.E.S M.S P.E.S

E.S – Earth Shadow

WORST CASE ECLIPSE–EARTH AND MOON SHADOW

PES

MS

48

LIT

27.5

PES

42.5

MS

PES

ES

48

51 9.5

MS

PES

48

42.5

LIT

27.5

MS

48

9.5

Duration in minutes MS –Moon Shadow LIT - Illumination period PES – Partial Earth Shadow ES – Earth Shadow

Total Duration: 6.7 hours

SUMMARY OF LUNAR ECLIPSES (2008-2010) Date

Eclipse Type

Saros

Umbral Mag

Eclipse Duration (hh:mm)

Geographic Regions of Eclipse Visibility

21 Feb, 2008

Total

133

1.111

16 Aug, 2008

Partial

138

0.813

03:36 00:51 03:09

09 Feb, 2009

Penumbral

143

-0.083

-

E Europe, Asia, Aus, Pacific, W N.A

07 Jul, 2009

Penumbral

110

-0.909

-

Aus, Pacific, Americas

06 Aug, 2009

Penumbral

148

-0.661

-

Americas, Europe, Africa, W Asia

31 Dec, 2009

Partial

115

0.082

01:02

Europe, Africa, Asia, Aus

26 Jun, 2010

Partial

120

0.0542

02:44

E Asia, Aus, Pacific, W Americas

21 Dec, 2010

Total

125

1.262

03:29 01:13

E Asia, Aus, Pacific, Americas, Europe

C.Pacific, Americas, Europe, Africa S.America, Europe, Africa, Asia, Aus

ISSDC Context Payload Reception Stations

S/C control center

Time Allocation Committee Science Working Group

Science Data Users

Space Science Mission Projects S/W Developers – data products, tools

ISSDC Payload Developers Payload Operation Centers

Principal Investigators

ISSDC functions •

Primary Functions – Ingest / Archive / Data Management – Data processing – Search & Order / Access & Dissemination

– Interface to Spacecraft control centers, Data reception centers, Payload designers, Principal investigators, Mission software developers and Science data users

ISSDC facilities • Server and Storage Support Area • Network Support Area • Public Network Access Workspace • Private Network Access Workspace • SATCOM Network Access Workspace • Software & System Support Area • System Administration Workspace

• System test and Maintenance Support Workspace • Development, Integration and Test Support Workspace • Operations Area ( IDSN Ops facility)

OVERALL DATA FLOW DIAGRAM Chandrayaan-1 Ground Segment

S-LBT (RT- 2) S-LBT (Dwell) X-LBT (PB – SSR#2) Remote View (SSR #2) S-Band Tracking data TC Ack

PAYLOAD OPERATIONS Look angles

SCC

TC Schedule file

Cmd Request messages

DSN

Processed QLD input

Bangalore – 18 / 32 m

Archived PVAT

P/L Raw Data: TMC – APS 1, 2, 3, HySI, LLRI, HEX, C1XS, M3, SIR-2, SARA, MIP, RADOM SS + Gyro data (SSR #2)

EXTERNAL DSN Bearslake APL Tracking NASA data LBT (RT + Dwell) P/L raw data

OBT-UT Ref. Ephemeris Events Cmd schedule Pass schedule Instrument health

ISSDC

POC 1.TMC & HysI - SAC 2.LLRI - ISAC 3.HEX - PRL

4.CIXSA - RAL

Ephemeris Events 5.CIXSB - ISAC PVAT Command Acknowledgement 6.SIR-2 – Max Instrument Telemetry (P/L data) Planck, Germany Instrument House keeping OBT - UT 7.SARA - VSSC File-ready Notification email 8.miniSAR - APL

Command Messages Products & E-mail notification

9.M3 - JPL

Lunar DEM Generation 

Global DEM generation from TMC triplet 

More than 100000 image triplets



Grid interval size ~25-50m



LLRI data use to be explored

ISRO Moon Atlas • Cover the entire moon surface at Uniform Scale (1:25,000/50,000) • Consists of TMC & HySl Image and Image mosaics • Contains Digital Elevation Model derived from TMC • Softcopy & Hardcopy both • Vector and Raster databases

High level Data products 

The high level data products from the AO payloads are 



Near Infra-red Spectrometer (SIR-2) 

Spectroscopic data corrected for dark bias and bad pixel data



Radiometric and wavelength corrected data



Details of lunar surface in various geological, mineralogical and topographical units

Sub-keV Atom Reflecting Analyser (SARA) 

Images of energetic neutral atom distributions for specific energy and mass group and time-dependent plots of total fluxes for them (CENA)



Energy spectra for the four specified mass group atoms



Linear plot of proton fluxes(SWIM)

High level Data products (contd.) Miniature Synthetic Aperture Radar (MiniSAR) •

Level 1 products ortho-rectified and resampled into oblique map projections

•

Four mosaics composed of multiply acquired data sets produced for regions above 80º lunar latitude using level2 stokes parameters

Moon Mineralogy Mapper (M3) •

Radiance at sensor and seleno-corrected spectral image cubes

•

Reflectance data

Radiation Dose monitor Experiment (RADOM) •

Estimated radiation dose equivalent from GCR,SPE and radiation dose maps around moon

•

Moon environment characteristics

Possible Fusion Data Products • Elemental composition and Mineral Maps:M3,SIR-2,HySI, C1XS,SARA • DEM from TMC with LLRI topo map • Magnetic anomaly map of SARA with TMC base map • Polar region map from MiniSAR, LLRI overlaid with TMC base map • Projection of X-ray line abundances from C1XS and HEX against DEM made from fusion of TMC and LLRI data • Fusion of mineral map, elemental composition map with topographic map • Integration of data from earlier lunar missions with that of Chandrayaan-1

Visualization tools and other utilities 

Intended for public outreach and awareness.



Tool would show at a given point of time, how much imaging is done on the globe of Moon.



Overlay of processed data showing the information layers available for various instruments

Data Fusion (R&D)and other utilities (in the form of software) 

User can generate fusion products using the utilities provided at ISSDC (generated by science teams or data processing teams) with required data download facility. This also includes visualization tools for looking at a particular area of interest

Education and Outreach Activity Plan  Comprehensive education and public outreach programme is under development  Activities aimed towards a broad range of ages and abilities  Education and categories

Public

Outreach

programme

planned

in

four

 Formal education

•

As part of basic curriculum for high school level students, providing resource and support material-this is a long term strategy / plan

•

Scientific research at university level (e.g. PLANEX Programme of ISRO)

 Semi-formal education •

Introducing project work as part of school curriculum (similar to that in for B.Tech)

•

ISRO may provide tool kits (involvement of industries)

Education and Outreach Activity Plan (contd.)  Informal Education • Seminar, talks on Moon,Chandrayaan-1 • Essay contest

• Exhibition • Team with local planetary society members, amateur observers /sky watchersto share and exchange ideas • Use website • Moon globe on website –similar to Google-Earth using TMC DEM

 Public Outreach • Popular publication • Broadcast over national and local Radio and Television Network • Use of Website

• For common public cultural, mythological and historical stories related to Moon

Education and Outreach Activity Plan (contd.) A few sample questions which may be considered as project topic:

• Calculate distance between scale models of Earth and Moon • To learn about locations and geology of sites identified by • Chandrayaan-1 science team • Compare the process of regolith formation on the Moon and the relative process on Earth • Design a spacecraft for going to moon and choose a landing site of interest • Construct a model of lunar rover • Future lunar mission ideas

Outreach Implementation Plan  The outreach activity would be implemented in steps •

Mission update on ISRO/ Chandrayaan-1 Website from T-90 day

•

Announcement of Opportunities towards Formal and Informal Outreach activities seeking proposals from different groups

 Collaborative agencies would be selected from Research Laboratories,School, Colleges, Universities, National and Regional science museums and Planetariums based on the activities •

After obtaining approval from DOS/ISRO, activities would be carried out and monitored in collaboration with P & PR Unit ISRO

To Conclude – Why to go to Moon… 

The first, of course, the scientific goals that despite many missions of the past, the question of origin and evolution of Moon still remains unanswered



The second objective is the challenges posed by technology and mission planning



The third factor is such a mission can inspire the new generation by the sheer excitement that such a flag-ship mission will evoke.



India cannot afford to lose out in its ability to pursue exploration