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Deep Space Optical Communications Discovery Technology Day

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1 Deep Space Optical Communications Discovery Technology Day
National Aeronautics and Space Administration Space Technology Mission Directorate Game Changing Development Program Deep Space Optical Communications for Discovery Technology Day Presented by: Abhijit (Abi) Biswas 9-April-2014 This document has been reviewed and determined not to contain export controlled technical data.

2 Deep-Space Optical Communications (DSOC) Overview, Capabilities and Footprint
Spacecraft Flight Laser Transceiver (FLT) 4W, 22 cm dia. 1550 nm Beacon & Uplink 1030 nm 292 kb/s @ 0.4 AU CBE MASS (kg) 28 Mass margin (%) 30 CBE POWER (W) 76 Power Margin (%) 31 Optical Head: 45 x 45 x 49 cm (95E3 cc) Elect. Box: 29 x 23 x 23 cm (15E3 cc) Performance using 4W average laser power w/22 cm flight transceiver to 5m ground telescope Ground Laser Transmitter (GLT) Table Mtn., CA 5kW, 1m-dia. Telescope Deep Space Network (DSN ) Ground Laser Receiver (GLR) Palomar Mtn., CA 5m-dia. Hale Telescope Optical Comm Ops Ctr. JPL, Pasadena, CA TBD MOC This document has been reviewed and determined not to contain export controlled technical data.

3 DSOC Key Characteristics
Silicon Carbide Telescope & Optics (Front cover not shown) Deep-space optical communications characteristics Photon-efficient communications Pulse-position modulation w/ Near capacity achieving codes Laser beacon + Earth image assisted pointing from space Integrates new technologies green outline Flight Laser Transceiver (FLT) Assembly Uplink receiver Downlink transmitter Ground Laser Receiver(GLR) Photon-counting ground detectors 60% Eff. WSi nanowire arrays Hale Telescope Ground Laser Transmitter (GLT) 1030 nm Ground Lasers OCTL Telescope Ground Segment Point-Ahead Mirror Photon-Counting Space Receiver 40% QE Rad Tolerant Laser Transmitter Electronics Box 1550 nm Space Laser Transmitter Electronics processing & control cards, firmware, software, clock Spacecraft Disturbance Isolation Assembly 50 dB rejection

4 Implementation: Spacecraft/Launch Assumptions
Deep-Space Optical Communications Operating Angular Disturbance (rad2/Hz) PSD of vibration assumed for indicated performance (141 rad RMS) RMS Disturbance power spectral density (PSD) PSD shown in figure on right RMS Instrument interface attitude knowledge error, roll about LOS to ground (1) 150 rad TBC Spacecraft cross-range velocity knowledge error (1) 5 m/s Spacecraft Pointing Control (3) 5mrad Comparable S/C pointing MRO : mrad (Ka/X) JUNO: mrad (Ka/X) Kepler: mrad (Ka) DAWN: 11 mrad (X) Contamination Control CL 300 User Data Interface GigE

5 Implementation: FLT & Ground Station Assumptions
Flight Laser Transceiver (FLT) Based on JPL design that had Concept Review in August 2010 Interface to spacecraft C&DH for downlinking user data over optical link Data-rates shown on p.1 Point-ahead angles of  400 rad (TBC) Doppler of 50 ppm (TBC) Beacon assisted pointing architecture presumed (i.e. no “handshaking”) Support uplink commanding max rate of AU 2-way ranging precision of 30 cm (TBC) Sun-angle limitations Sun-Earth-Probe angle > 12 Sun-Probe-Earth angle > 3 for operations (survive sun-pointing) Designed for TID of 20 krad

6 FLT TRL-Status All technologies advance to TRL-6 prior to EO FY17
Silicon Carbide Telescope & Optics (Front Cover shown) TRL-6 Flight Laser Transceiver (FLT) Assembly Uplink receiver Downlink transmitter Point-Ahead Mirror TRL-6 Photon-Counting Space Receiver TRL 2-3 Flight Electronics TRL 4-5 Laser Transmitter TRL 4-5 Spacecraft Disturbance Isolation Assembly TRL-4

7 NOTIONAL SCHEDULE DISCOVERY DSOC TECH. DEVELOPMENT DSOC FLT
Concept Study Reports 4/16 Down Select Mission 10/16 CDR 9/18 Launch NLT 12/21 DISCOVERY DSOC FLT DSOC GROUND Selection Phase A Studies 5/15 Phase B Start 11/16 PDR 11/17 SIR 5/19 PSR 11/20 Phase A Start 6/17 4/19 3/18 7/18 SRR DSOC TECH. DEVELOPMENT TRL-6 Ground Complete 2/21 I&T

8 Planned AO Library Content
Fact Sheet for Deep Space Optical Communication Technology Day Charts Published papers/reports on Deep-Space Optical Terminals (DOT) Technology characteristics Laser communication terminal interface details as they mature Joint weather statistics Palomar Mountain & Table Mountain, CA Contact information for queries and questions regarding interfaces

9 Point of Contact Abhijit (Abi) Biswas Sr. Optical Engineer
Optical Communications Group Jet Propulsion Laboratory, California Institute of Technology Pasadena, CA 91109 Tele: (818)

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