CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA 29789 Space Data Systems Applications in the iPAS.

Slides:



Advertisements
Similar presentations
Jet Propulsion Laboratory California Institute of Technology Disruption Tolerant Network Technology Flight Validation Report by Ross M. Jones Jet Propulsion.
Advertisements

1 Comments on Delay Tolerant Network (DTN) October, 2008 Berlin, Germany Takahiro Yamada, JAXA/ISAS.
SIS_DTN 1 DTN HOSC DTN Gateway Test Report May 2010 Cleveland, OH 2012.
ISS Institutional DTN Overview for CCSDS
May 17, Capabilities Description of a Rapid Prototyping Capability for Earth-Sun System Sciences RPC Project Team Mississippi State University.
METERON Operations Environment and Prototype Robotic Services M. Sarkarati, J. Raymaekers, K. Nergaard European Space Agency.
Dd12 – operations technology facility 8 October2010 (MIRA) M otion I magery and R obotics A pplication Project (MIRA)
March 2004 At A Glance ITOS is a highly configurable low-cost control and monitoring system. Benefits Extreme low cost Database driven - ITOS software.
Exemplar CFS Architecture
Lunar Surface DTN Scenarios DTN /10/09 Lunar Electric Rover Lunar Relay Satellite Flight Controllers Lunar Communications Terminal S-Band/Ka-Band.
NASA Goddard Space Flight Center Direct Readout Laboratory NPP/JPSS HRD/LRD Status Patrick Coronado NASA Goddard Space Flight Center directreadout.sci.gsfc.nasa.gov/ipopp.
G O D D A R D S P A C E F L I G H T C E N T E R 1 The Trade Between CCSDS and HDLC Framing on Global Precipitation Measurement David Everett and Jonathan.
Planes, Trains and DTN (Delay Tolerant Networking) Ashton G. Vaughs Jet Propulsion Laboratory Copyright 2009 California Institute of Technology Government.
Open Source DTN for ISS Payloads Concept Proposal, 05-Jun Open-source DTN communication software for ISS Payloads Kevin K. Gifford BioServe Space.
AMS TIM, CERN Apr 12, 2005 AMS Computing and Ground Centers Status Report Alexei Klimentov —
SM&C Mission Operations Services: Prototype Demonstration SM&C Core & Common Layer Demonstration ESA/BNSC Collaborative Prototype Presented by: Roger Thompson.
1 CCSDS File Delivery Protocol for Flight Applications Art Ferrer NASA/GSFC, Code 582 Fourth Space Internet Workshop June 2004 Hanover, MD.
SIS_DTN 1 SIS-DTN Forward Planning October 2013 San Antonio Fall 2013.
Glenn Research Center Networks & Architectures Branch Communications Technology IETF73 - IRTF DTNRG Meeting November Space-based DTN Low Earth Orbit.
Space Data Routers for Exploiting Space Data Martin Götzelmann, VEGA Vassilis Tsaoussidis, DUTH Sotirios Diamantopoulos, DUTH Ioannis A. Daglis, NOA Theodore.
DTN Network Management Will Ivancic Ed Birrane
International Workshop on Satellite and Space Communications 2009, IWSSC 2009, 9-11 September 2009, Siena, Italy Evaluation of CCSDS File Delivery Protocol.
1 In-Space Cross Support Using Delay / Disruption Tolerant Networking Keith Scott 15 October, 2008 Berlin, Germany October 15, 2008.
Space-Based Network Centric Operations Research. Secure Autonomous Integrated Controller for Distributed Sensor Webs Objective Develop architectures and.
SISG - SSI ADD Service, Physical, and Protocol View Document Figures Ver 0.4, 2 Sept 09 Peter Shames, et al.
June 2004 SIW-4 - IP in Space Implementation Guide 1 Handbook for Using IP Protocols for Space Missions James Rash - NASA/GSFC Keith Hogie, Ed Criscuolo,
CHIPSat Cosmic Hot Interstellar Plasma Spectrometer Spacecraft Julius-Maximilians-Universität Würzburg S: Telematik in der Raumfahrt Prof. Dr. Schilling.
Page No. 1 Kelvin Nichols Payload Operations and Integration Center EO50 Delay Tolerant Networking (DTN) Implementation on the International Space Station.
Final Version Micro-Arcsecond Imaging Mission, Pathfinder (MAXIM-PF) Mission Operations Tim Rykowski Jeffrey Hosler May 13-17, 2002.
10-Dec-2012-cesg-1 Presentation to ESTEC NH Conference Centre, Nordwijkerhout, Netherlands Hosted by ESA/ESTEC 8 April 2014 CCSDS Space Internetworking.
V. Tsaoussidis, DUTH – Greece
DTN Network Management Scenarios and General Requirements Will Ivancic
1 15 November 2004 CCSDS Security Architecture 15 th November 2004 Toulouse.
Status of JAXA’s DTN activity DTN WG CCSDS Spring Meeting 2012 Shinichi Inagawa / Kiyohisa Suzuki Japan Aerospace Exploration Agency 1 CCSDS Spring Meeting.
CCSDS Fall Meeting at ESTEC
NASA Space DTN Program Keith Scott SIS-DTN WG Wednesday Afternoon 28 October 2009SIS-DTN 1.
NASA AMS Prototyping Activities Scott Burleigh Jet Propulsion Laboratory, California Institute of Technology 11 March 2008.
The CCSDS Cislunar Communications Architecture Keith Scott The MITRE Corporation CCSDS Meeting January 2007.
20 November 2008 SB-1 First Look at the Deep Impact DTN Experiment (DINET) Scott Burleigh Jet Propulsion Laboratory California Institute of Technology.
March /5/2016 At A Glance STARS is a real-time, distributed, multi-spacecraft simulation system for GN&C technology research and development. It.
CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Space Data Systems Applications in the iPAS.
NASA MSFC Mission Operations Laboratory MSFC NASA MSFC Mission Operations Laboratory Ku - Band, DTN, and enhanced payload utilization.
BITTT—Beijing Institute of Tracking and Telecommunications Technology
17 November Asynchronous Message Service (1 of 3) In addition to file transfer, event-driven asynchronous message exchange may also be useful for.
CEOS WGISS Meeting, Hanoi May CCSDS Liaison Consultative Committee on Space Data Systems Wyn Cudlip BNSC/QinetiQ Presentation.
DTN Network Management Scenarios and General Requirements Will Ivancic
Ground Control AERSP 401A. Ground System’s Basic Elements Mission Elements –Control the space segment or handle mission data, and includes: Ground Stations.
February 14, 2013 POIWG Technical Overview CR / HM-3430 Ku Forward Capability.
NASA MSFC Engineering Directorate Huntsville, Alabama 10/29/2012 HOSC DTN Activities October 2013.
NASA MSFC Engineering Directorate Mission Operations Laboratory MSFC NASA MSFC Engineering Directorate Mission Operations Laboratory Increment 19/18 Soyuz.
S-band Telemetry Description DMC 211 October 2015.
NASA MSFC Mission Operations Laboratory MSFC NASA MSFC Mission Operations Laboratory Kelvin Nichols, EO50 March 2016 MSFC ISS DTN Project Status.
Page No. 1 Overview Kelvin Nichols Payload Operations and Integration Center EO50 SSCN Delay Tolerant Networking (DTN)
Chapter 10 Telemetry Downlink
NASA AES DTN Status Keith Scott CCSDS Meetings, Spring 2016
Low Earth Orbit Results
HOSC DTN Gateway Test Report
Service, Physical, and Protocol View Document Figures
AMS Prototyping Activities
ETR-NASA DTN Phase-1 Test Results
SIS-DTN WG Wednesday Afternoon
ISS Institutional DTN Overview for CCSDS
METERON Operations Environment and Prototype Robotic Services
Ku - Band, DTN, and enhanced payload utilization
Integrating CCSDS Electronic Data Sheets into Flight Software
Adam Schlesinger NASA - JSC October 30, 2013
Technology for a NASA Space-based Science Operations Grid Internet2 Members Meeting Advanced Applications Track Session April, 2003 Robert N. Bradford.
Stephen A. Townes Chair & General Secretary, CCSDS
Jeff Dutton/NASA COR August 26, 2019
Presentation transcript:

CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Space Data Systems Applications in the iPAS Pathfinder Laboratory Tom Rich Operations Technology Facility Mission Systems Division / Mission Operations Directorate NASA Johnson Space Center Collaborators: Leigh Torgerson / JPL, Bill Othon / iPAS Lead / JSC Engineering Directorate

2CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA integrated Power, Avionics, and Software (iPAS) Pathfinder Lab Overview The iPAS is an integrated hardware/software test and evaluation environment, in support of current and future spacecraft development The iPAS has two main elements –A common onboard avionics, hardware, and software architecture that can be applied over multiple missions –A common testbed framework that supports integrated hardware/software testing for multiple mission applications The iPAS includes the following (non-flight qualified) components: –Core Flight Software (GSFC) –Commercially available Proton and S950 Flight Computer boards –Power and propulsion systems based on representative flight hardware –A realistic flight deck based on the Orion Multi-Purpose Crew Vehicle (MPCV), including realistic flight controls and displays –A Space Data System based on CCSDS protocols

3CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Current iPAS Simulated Mission The “Orion” Multi-Purpose Crew Vehicle will rendezvous with an ISS derived “waypoint” vehicle in a halo orbit about the earth-moon L2 Lagrangian point. –1.3 seconds OWLT –Easy to stationkeep: 10 M/sec per year –At the current max range of the MPCV –Halo orbit: constant line of sight L2 40 K miles Moon Earth 240 K miles Moon Halo orbit X X X X

4CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA iPAS Space Data System Rationale Mission Operations Goals for iPAS: Apply internationally standardized protocols to spacecraft command, telemetry, video, and file transfer in a realistic scenario where light-time delay becomes significant –Consultative Committee for Space Data Systems (CCSDS) standards: Spacecraft Monitoring and Control (SM&C parameter and action services) Asynchronous Message Service (AMS) Delay / Disruption Tolerant Networking (DTN) Licklider Transmission Protocol (LTP) –Provides reliable space to ground comm –“TCP in space” Bundle Streaming Service (BSS) –Provides a real-time “as-is” data stream, non-reconstituted –Also provides a “cleaned up” data stream, after missing data packets have been automatically detected and retransmitted by LTP CCSDS File Delivery Protocol (cfdp) –Provides reliable file transfer in the space environment Raise the SM&C / AMS / DTN / LTP technical readiness levels Promote the acceptance and application of these standardized protocols, which will increase center-to-center interoperability and lower per-mission costs.

5CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Multi-Control-Center iPAS Overview Telemetry Command MPCV Hardware / Software iPAS Lab, JSC Bldg. 29 (Green) DSN Operations Center JPL Protocol Test Lab (Yellow) OTF, JSC Bldg. 30JPL HOSC, MSFC (Peach) Simulated Mission: Dock with gateway vehicle in halo orbit about the Earth-Moon L2 point; final 2000 meters

6CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Control Center Simulations – Operations Technology Facility Flight Computer iPAS Lab, JSC Bldg. 29 DSOC Simulation – JPL PTL (sim Antenna Site) Multi-Control-Center iPAS Telemetry and Command System Communication Environment – datapub2 – iPAS Lab, JSC Bldg. 29 CCSDS Packet to SM&C Converter; SM&C Parameter & Action Provider DTN Onboard AMS Publisher AMS/BP/LTP ION MSKView Display Control Center #3 SM&C Parameter / Action Consumer DTN UDP/BP/AMS ION MPCV Core Flight Software Proton/S950 FCs den08 Apposite Space Link Simulator 2% packet Drop rate (downlink) 4 sec. OWLT Packet Record/ Playback CCSDS Space Packets (UDP) den07 DTN Ground AMS Publisher LTP/BP/UDP LTP/BP/STCP LTP/BP/DGR ION LTP DSNet NISN LTP UDP DSNet AMS MSKView Display Control Center #5 SM&C Parameter / Action Consumer DTN STCP/BP/AMS ION STCP DSNet AMS MSKView Display Control Center #6 SM&C Parameter / Action Consumer DTN DGR/BP/AMS ION AMS DGR DSNet Onboard ECLSS Fan

7CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA SM&C MSKView

8CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Multi-Control-Center Demo

9CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA iPAS Bay 2 iPAS MJPEG Video Using BSS Communication Environment – Data Publisher Workstation, iPAS Bay 2 Control Center Simulation – Operations Technology Facility Axis 214 PTZ Network Camera (encoder + http server) Motion JPEG to BP Converter DTN BP/LTP MJPEG Missing Frame Detector BSS Realtime VLC Display DTN node 3 UDP/BP/BSS JPL den08 Downlink Emulation 2% packet Drop rate 4 sec. OWLT Motion JPEG HTTP MJPEG Missing Frame Detector BSS Playback VLC Display UDP Realtime Stream UDP Playback Stream (40 seconds back into database) Direct Camera Feed VLC Display BSS Controller JPL den07 ltp to udp converter

10CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Bundle Streaming Service Video Demo

11CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Backup

12CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Bandwidth / Overhead Data Point iPAS test conditions (NON OPTIMIZED!) –iPAS telemetry is primarily 8byte DP floating point –600 parameters –10 Hz data rate SM&C / AMS / BP / LTP throughput: –440 kbps in / 700 kbps out –Processing 65% of input data stream (5 of 6 available APIDs) –700 / (440 *.65) = 2.4 –140% overhead (NON OPTIMIZED!) As payload size increases, overhead will decrease.

13CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Bandwidth / Overhead Data Point BP / LTP throughput: –126 kbps in / 128 kbps out –2% overhead

14CCSDS Fall 2013 Approved For Public Release via the NASA Science and Technical Information Process DAA Forward Work (Potential) Add 2-way voice / audio Add service prioritization / Quality of Service Tune parameters to lessen overhead Add Network Management Add video pub/sub capability (using AMS) Add Robotics API Delegate (RAPID) Evaluate h.264 (compressed) video, rather than Motion JPEG