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NASA Space Networking NASA’s Deep Space Communications & Navigation: Expanding our Presence in the Solar System Jim Schier NASA Space Communications and.

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Presentation on theme: "NASA Space Networking NASA’s Deep Space Communications & Navigation: Expanding our Presence in the Solar System Jim Schier NASA Space Communications and."— Presentation transcript:

1 NASA Space Networking NASA’s Deep Space Communications & Navigation: Expanding our Presence in the Solar System Jim Schier NASA Space Communications and Navigation Office AIAA Space 2008 September 2008 Presented at CCSDS CSSA WG, 13Oct08, Peter Shames

2 Agenda Context for Change Communications Navigation
Transition from X- to Ka-band for greater bandwidth Replace 70m subnet with arrayed antennas for robustness & scalability Optical communication for vastly greater bandwidth SW Defined Radios for post-launch reprogrammability Navigation Autonomous landing & hazard avoidance technology for precision EDL Lunar satellite & beacon-based surface navigation for high precision landing & roving Network Integration & Interoperability Standardized services across networks Enhanced interoperability for expanding presence across the solar system Conclusion

3 Context for Change Networks reorganized under Space Operations Mission Directorate into the Space Communications and Navigation Office (SCaN) charged with these priorities: Transition towards a single, unified mission support architecture Manage ground & space-based facilities of existing networks (Space Network/Tracking & Data Relay Satellite System, Near Earth Network, Deep Space Network) and future Lunar and Mars Networks Oversee evolution of terrestrial network architecture (NASA Integrated Services Network) managed by CIO as part of Agency infrastructure Automate capabilities and develop technology to reduce costs Advocate and develop communications standards Advocate and defend spectrum use Strengthen inter-Agency cooperation and partnership Build international cooperation and interoperability

4 SCaN Notional Integrated Communication Architecture in 2025 Timeframe
Titan Neptune Saturn Uranus Moon Antenna Array Pluto Charon Jupiter Cx MCC ISS MCC SCaN Integrated Service Portal Mars NISN Solar system wide coverage Anytime, anywhere connectivity for Earth, Moon, and Mars Integrated service-based architecture Space internetworking (DTN) Leverages new technology (optical, arraying, software radios, …) Internationally interoperable Venus SCaN Microwave SCaN Optical NISN 4 Sun Mercury

5 Integrated Service Architecture
Services across networks migrate to open standards (CCSDS) for both Ops Center & Spacecraft interfaces Management services for mission planning, scheduling & execution standardized

6 Increasing Interoperability
Ground, Orbiter, & Surface Interoperability Supported Agency Earth Moon Supporting Agency 2 Supporting Agency 1 Standard services will include: Relaying services (routed and store-and-forward deliveries) for Files, Space Packets, Commands & Telemetry Positioning services (ranging and orbit determination) Timing services (clock distribution and synchronization) Management services (service requests & reporting, data accountability, configuration management) Standard protocols form the basis of an open, internationally interoperable architecture: Surface links: IEEE 802.x Surface-to-orbiter links: CCSDS Proximity-1 or its enhanced version Orbiter-to-earth and direct-to-earth links: CCSDS TC/TM Space Data Link with Space Packet Ground links: CCSDS SLE on top of TCP/IP End-to-end: CCSDS CFDP or DTN

7 Data rate from Mars: 100+ Mbps 3m Telescope using array of 1m devices
Optical Comm Roadmap Goals established by Administrator Griffin: Operational lunar optical communications by 2018 Operational Mars optical communications by 2023 Accelerated technology development program being formulated addressing ground & space-based terminal options Flight demo on LADEE in 2011 Deep space user terminal (50 cm, 10 W) Data rate from Mars: 100+ Mbps Mobile Optical Ground Terminal Demo Deep Space Optical Relay 3m Telescope using array of 1m devices

8 Software Defined Radios (SDR)
SDRs provide remote reprogrammability for: Reconfiguration of communication and navigation functions according to mission phase Post-launch software upgrades Use of common hardware platforms for multiple radios over a variety of missions Agency SDR Infrastructure Space Telecommunications Radio System (STRS) SDR Standard Architecture Specification (STRS Release 1.1, May 07) HW and SW Component Library with broad early acceptance criteria, becoming more stringent as the infrastructure matures Projects select and procure library components as needed Design Reference Implementation Specifications using standard-compliant library components Tools and Testbeds for SDR design, development and validation Demonstrations of STRS-compliant units on the ground and in space SCaN CoNNecT Orbiting Testbed to fly in 2011 on ISS

9 Mars Downlink Data Rate Possibilities
DSN Configuration Spectral Band Spacecraft Transmitter Power Notes Data rate, Closest (0.6 AU) Data rate, Farthest (2.6 AU) 1 1 34m antenna X-Band 100 Watts MRO-class today * 20 Mbps 1 Mbps 2 Ka-Band 35 Watts Feasible today 28 Mbps 1.5 Mbps 3 3 34m antennas or equivalent Enabled by robustness plan 84 Mbps 4 Mbps 4 1 34m antenna or equivalent 180 Watts Transmitter already developed and commercialized (LRO, Keppler) 144 Mbps ** 8 Mbps 5 432 Mbps ** 23 Mbps 6 7 34m antennas or equivalent Enabled by 70m replacement 1.0 Gbps ** 54 Mbps * Reference spacecraft is MRO-class (power and antenna), Rate 1/6 Turbo Coding, 3 dB margin, 90% weather, and 20° DSN antenna elevation ** Performance will likely be 2 to three times lower dues to need for bandwidth-efficient modulation to remain in allocated spectrum LJD - 9 09/18/08

10 Conclusion SCaN infrastructure is undergoing extensive modernization to provide continuous service for decades to come Arrayed antennas, RF enhancements, and new optical relays are being developed to continue to provide orders of magnitude improvement in data rates & robustness to meet the needs of increasingly complex solar system missions Standardization of services will enable nearly seamless interoperation across NASA’s networks, more standardized & cheaper mission subsystems Integrated service portal will standardize planning & execution enabling mission programs & Centers to further lower costs International interoperability will enhance mission flexibility & provide increasing opportunities for collaboration on major initiatives such as Mars Sample Return

11 Descent & Landing Navigation
Autonomous Landing Mode (Ambient Lighting): Autonomous landing without active optics provides a self-contained system with IMUs 100 m (3-σ) landing accuracy assuming no emplaced infrastructure (i.e., relays) Passive optical system + strobe lights for use in the last 300 m for low light landing situations IMU data required for thrust level sensing All data (RF, Optical, LIDAR/RADAR and IMU) processed in real-time for continuous trajectory update to closed-loop guidance Infrastructure-aided Landing Mode: LN-aided descent/landing augments passive optical-based landing system by providing accurate radiometrics to maintain trajectory knowledge through powered descent and landing in view of emplaced landing aids 1 meter level landing accuracy Landing aids near outpost are a combination of passive optical devices and Lunar Comm Terminals that operate like the LRS Radiometrics disciplined by an atomic clock Lunar Relay Satellite (LRS) LN 1-Way S-Band phase & range LCT LN 1&2-Way S-Band phase & range LRS Op Nav Images aided with passive targets LIDAR for altitude, range, & range rate IMU User in Orbit EDL

12 Lunar Relay Satellite (LRS)
Surface Navigation Surface mobility may involve excursions that are 500+ km from the outpost Farside trek has no DTE or LCT Position knowledge < 30 m needed to navigate to desirable spots and back home IMU insufficient for in-situ navigation (1200 m long term accuracy) LN tracking and imaging required Roving navigation requires periodic stops to obtain in-situ static position fixes ~every min In-situ static positioning fixes require LN radiometric tracking to obtain inertial position Landmark tracking coupled with star tracking to obtain map relative position Combined process resolves the ‘map tie’ error between inertial and map relative solutions Static position to < 10 m in a few minutes Roving navigation is initialized via the static position fix and then continues with real time navigation processing IMU data is dead reckoning velocity LN radiometric tracking to solve for position and velocity and ‘disciplining’ IMU drift Image data not taken while roving LRS Lunar Relay Satellite (LRS) LN 1 & 2-Way S-Band Doppler & range LN 1-Way S-Band Doppler & range Landmark Tracking IMU Rover

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