Advanced Avionics Systems for Dependable Computing in Future Space Exploration

1. Advanced Avionics Systems for Dependable Computing in Future Space Exploration Leon Alkalai, Savio Chau, Ann Tai Center for Integrated Space Microsystems Jet Propulsion Laboratory California Institute of Technology GOMAC – 2002 March 12th, 2002 leon@cism.jpl.nasa.gov URL: http://cism.jpl.nasa.gov Tel. 818 354-5988 Fax. 818 393 5013 1

2. Potential Customers:Mars 09 Smart Lander/Rover Mission • Conduct Significant • Science* • Sub-surface drilling • In-situ soil/rock analysis • Atmospheric measurements SURFACE MOBILITY • Demonstrate Next-Generation • Lander/Rover Capabilities • Global access • latitude range • surface elevation • rugged terrain • Accurate/safe landing • “Go-to” mobility • Extended mission operations GUIDED ENTRY • Approach • Strong, multi- • disciplinary team • NASA centers • Industry • Universities • Early pre-project • with extensive • technology program HAZARD DETECTION/AVOIDANCE *No “strawman” payload yet defined, examples of possible experiments listed ROBUST TOUCHDOWN SYSTEM 2

3. Potential Customers:Solar System Exploration (circa 2008) Europa Orbiter/Lander Cassini/Huygens Titan Explorer Comet Nucleus Sample Return Galileo-Europa • Exploring Organic Rich Environments: • Extreme Radiation Environments • Extreme Temperature Environments • Long Duration missions • Long latency of communications • highly autonomous operations • miniaturization of systems • design for high survivability, fault-tolerance, and high availability Pluto/Kuiper Express 3

4. Potential Customers:Astrophysics (2009) Laser Interferometry Space Antenna (LISA) Space Interferometry Mission (SIM) • Space based Interferometry • High precision metrology • Pico-meter laser interferometry • Highly miniaturized electronics • High performance computing • Micro-Newton Thrusters • Disturbance reduction control • High Performance inertial sensors 4

5. Dependable Computing in Previous Deep Space Missions • Typical Dual-String Designs for Spacecraft Point-to-Point Architecture Bus-Based Architecture Mass Memory Mass Memory Mass Memory Mass Memory Flight Computer Flight Computer Flight Computer Flight Computer I/O Interface I/O Interface Bus Interface Bus Interface Telecom Telecom Telecom Telecom Attitude and GN&C Attitude and GN&C Attitude and GN&C Attitude and GN&C Power Power Power Power Science Instruments Science Instruments Science Instruments Science Instruments 5

6. Dependable Computing in New Generation of Deep Space Mission • Characteristics of New Generation of Deep Space Missions: • Many missions focus on autonomous landers, rovers, sample return, etc. • Missions requirements are much more demanding: • Precision autonomous navigation, including Aero-Braking and Aero-Capture • Precision landing • Entry, Descent and Landing Hazard avoidance • Much higher processing requirements • Distributed processing • Much higher interface bandwidth requirements • Autonomous operation • High speed fault detection and recovery • The systems are physically smaller with higher functional density • Shrinking mission operation budget means smaller mission operations team • Must rely on on-board autonomous fault tolerance 6

7. High-Performance Fault-TolerantBus Architecture Research at JPL • Requirements for Distributed Processing, High Interface Bandwidth, and High Speed Fault Recovery Necessitate the Development of a High Speed Fault Tolerant Bus Architecture • Commercial-Off-The-Shelf (COTS) Bus Standards Are Highly Desirable Because of Cost, Availability, and Performance Benefits. • Two COTS Bus Standards Were Selected for the initial X2000 design: • the IEEE 1394 and I2C • However, These COTS Buses Are Not Designed for the Highly Reliable Applications Such As Deep Space Missions. Therefore, the Focus of the Research is How to Achieve Highly Reliable Avionics Bus Architecture Using COTS Bus Standards 7

8. NVM SFC NVM SFC Non- Volatile Memory Flight Computer NVM NVM NVM NVM NVM NVM Non- Volatile Memory Non- Volatile Memory Baseline X2000 COTS Bus Architecture 1 to N Computers N < 64 global memory SIO (SIO) SIO (SIO) I/O Interface Micro Controller (NVM) PCI PCI 1394 Bus - 100Mbps Power Control (Bus) (Symbolic, topology not shown) I2C Bus - 100kbps Power Control (Bus) 1394 Bus - 100Mbps I2C Bus - 100kbps Micro Controller (ACS) IMU Micro Controller (Power) IMU Single Master, Subsystem I2C Bus PCI Telecom Frame Grabber SFG Temp. Sensor Power Control Battery Control Switch Module (loads) Switch Module (loads) PCS BCS Sun Sensor Interface Sun Sensor RS422 ISI IMU RS422 Star Camera SSA Power Regulation & Control, Valve & Pyro Drive, Analog Telemetry Sensors Attitude Determination 8

9. Multi-Layer Fault Tolerance Methodology for COTS-Based Bus Architecture • Mutually Assisted Fault Isolation & Recovery • Different topology • Redundant bus sets • Diverse bus topology • Protocol Enhancements • Fail-Silence Protocol • Heartbeat & Polling • Isochronous Ack • Link Layer Fail-Silence • Watchdog timers System Level Redundancy (Layer 4) Design Diversity (Layer 3) Mutually Assisted Recovery (Layer 3: Design Diversity) Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) 1394 Bus Native Fault Tolerance (Layer 1) I2C Bus Native Fault Tolerance (Layer 1) 1394 Bus Native Fault Tolerance (Layer 1) I2C Bus Native Fault Tolerance (Layer 1) • Header & Data CRC • Ack Packets w. Error Code • Ack Packet Parity • Response Packet Error Code • Timeout Conditions • Port Enable/Disable • Ack bit Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 9

10. A Framework for the Design of Highly Survivable Avionics Systems using COTS Design Analysis Fault propagation path System Level Redundancy (Layer 4) Leakage = Q4 System Level Redundancy (Level 4) Design Diversity (Layer 3) Design Diversity (Layer 3) Leakage = Q3 Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) Enhanced Fault Tolerance (Layer 2) Design Diversity (Level 3) Leakage = Q2 Enhanced Fault Tolerance (Level 2) COTS # 1 Native Fault Tolerance (Layer 1) COTS # 2 Native Fault Tolerance (Layer 1) COTS # 1 Native Fault Tolerance (Layer 1) COTS #2 Native Fault Tolerance (Layer 1) Leakage = Q1 COTS Native Fault Tolerance (Level 1) Fault Propagation Model of Multi-Layer Design L. Alkalai, A. T. Tai, “Long-Life Deep-Space Applications,” Computer, IEEE, Vol. 31, No. 4, IEEE Computer Society, April 1998, pp. 37-38. S. Chau, L. Alkalai, and A. T. Tai, "The Analysis of Multi-Level Fault-Tolerance Methodology for Applying COTS in Mission-Critical Systems," in Proceedings of the IEEE Workshop on Application-Specific Software Engineering and Technology (ASSET'2000), Dallas, TX, March 2000. 10

11. NVM SFC NVM SFC Non- Volatile Memory Flight Computer NVM NVM NVM NVM NVM NVM Non- Volatile Memory Non- Volatile Memory X2000 Fault Containment Regions 1 to N Computers N < 64 global memory SIO (SIO) SIO (SIO) I/O Interface Micro Controller (NVM) PCI PCI Power Control (Bus) 1394 Bus - 100Mbps (Symbolic, topology not shown) I2C Bus - 100kbps Power Control (Bus) 1394 Bus - 100Mbps I2C Bus - 100kbps Micro Controller (ACS) IMU Micro Controller (Power) IMU Single Master, Subsystem I2C Bus PCI Telecom Frame Grabber SFG Temp. Sensor Power Control Battery Control Switch Module (loads) Switch Module (loads) PCS BCS Sun Sensor Interface Sun Sensor RS422 ISI IMU RS422 Star Camera SSA Power Regulation & Control, Valve & Pyro Drive, Analog Telemetry Sensors Attitude Determination 11

12. 1394 Bus 1 Backup Connections Bus 1 Bus 1 Bus 1 Bus 1 1394 Bus 2 Backup Connections #1 #2 #3 #4 Root Branch Branch Branch 1394 Bus 1 Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf I2C Bus 1 I2C Bus 2 1394 Bus 2 Bus 1 Bus 1 Bus 1 Bus 1 Leaf Leaf Leaf Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root #5 #6 #7 #8 1394 Bus 1 Backup Connections 1394 Bus 2 Backup Connections A Highly Reliable Distributed NetworkArchitecture for Future Missions • Support distributed computing • Rich set of redundant interconnections • Multi-layer fault tolerance design to ensure fault containment L. Alkalai, S. Chau, A.Tai, J.B. Burt, "The Design of a Fault-Tolerant COTS-Based Bus Architecture," Proceedings of 1999 Pacific Rim International Symposium On Dependable Computing (Prdc'99), Hong Kong, China December 16-17, 1999. Also, IEEE Trans. Reliability, Vol. 48, December 1999, pp. 351-359. A. Tai, S. Chau, L. Alkalai, "COTS-Based Fault Tolerance in Deep Space: Qualitative and Quantitative Analyses of A Bus Network Architecture" will appear in proceedings of HASE 99: Fourth IEEE International Symposium on High Assurance System Engineering, Washington DC Metropolitan Area, November 17-19, 1999. 12

13. 1394 Bus 1 Backup Connections 1394 Bus 2 Backup Connections Bus 1 Root Bus 1 Branch Bus 1 Branch Bus 1 Branch Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf 1394 Bus 1 I2C Bus 1 I2C Bus 2 1394 Bus 2 Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root 1394 Bus 2 Backup Connections 1394 Bus 1 Backup Connections Realization of Multi-Level Fault Protection Methodology Cable IEEE 1394 has a tree topology Enhanced Fault Tolerance (An Example) #1 #2 #3 #4 Design Diversity #5 #6 #7 #8 System Level Redundancy with Diverse Topology Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 13

14. X2000 Fault Protection Strategy 1394 Bus 1 Backup Connections 1394 Bus 2 Backup Connections #1 #2 #3 #4 Bus 1 Root Bus 1 Branch Bus 1 Branch Bus 1 Branch Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf 1394 Bus 1 I2C Bus 1 I2C Bus 2 1394 Bus 2 Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root #5 #6 #7 #8 1394 Bus 2 Backup Connections 1394 Bus 1 Backup Connections Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 14

15. X2000 Fault Protection Strategy • Possible Recovery Initiator • IEEE 1394 Root • IEEE 1394 IRM • IEEE 1394 Bus Manager • I2C Prime Master 1394 Bus 1 Backup Connections 1394 Bus 2 Backup Connections #1 #2 #3 #4 Bus 1 Root Bus 1 Branch Bus 1 Branch Bus 1 Branch Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf 1394 Bus 1 I2C Bus 1 Interrogate I2C Bus 2 1394 Bus 2 Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root #5 #6 #7 #8 1394 Bus 2 Backup Connections 1394 Bus 1 Backup Connections Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 15

16. X2000 Fault Protection Strategy 1394 Bus 1 Backup Connections #3 Failed 1394 Bus 2 Backup Connections #1 #2 #3 #4 Bus 1 Root Bus 1 Branch Bus 1 Branch Bus 1 Branch Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf 1394 Bus 1 I2C Bus 1 Reconfigure I2C Bus 2 1394 Bus 2 Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 1 Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root #5 #6 #7 #8 1394 Bus 2 Backup Connections 1394 Bus 1 Backup Connections Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 16

17. X2000 Fault Protection Strategy 1394 Bus 1 Backup Connections 1394 Bus 2 Backup Connections #1 #2 #3 #4 Bus 1 Root Bus 1 Branch Bus 1 Branch Bus 1 Branch Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf Bus 2 Leaf 1394 Bus 1 I2C Bus 1 I2C Bus 2 1394 Bus 2 Bus 1 Leaf Bus 1 Leaf Bus 1 Branch Bus 1 Leaf Bus 2 Branch Bus 2 Branch Bus 2 Branch Bus 2 Root #5 #6 #7 #8 1394 Bus 2 Backup Connections 1394 Bus 1 Backup Connections Next fault recovery needs repair before bus switching if this node fails 17

18. I2C Bus Fault Protection: Fail Silence Flight Computer Flight Computer Microcontroller I2C Bus Sensor Sensor Actuator Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 18

19. I2C Bus Fault Protection: Fail Silence Flight Computer Flight Computer Microcontroller Timeout Timeout Timeout Babbling I2C Bus Sensor Sensor Actuator Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 19

20. I2C Bus Fault Protection: Fail Silence Flight Computer Flight Computer Microcontroller Unmute Babbling Unmute Unmute I2C Bus Unmute Sensor Sensor Actuator Presentation for Paper “A Design-Diversity Based Fault-Tolerant COTS Avionics Bus Network. CL#01-1161 20

21. 1553B BC 1553B BC 1553B BC 1553 Bus Analyzer 1553B BC 1553B BC Architecture Testbed Configuration PCI Bus analyzer Built-In Power Supply Built-In Power Supply Built-In Power Supply cPCI bus (6U chassis) cPCI bus (6U chassis) cPCI bus (6U chassis) PMC PMC PMC 1394a I/F (Saderta) Empty Slot PPC 750 (Synergy) 1394a I/F (Saderta) Empty Slot Empty Slot Empty Slot PPC 750 (Synergy) 1394a I/F (Saderta) Empty Slot Empty Slot 1394a I/F (Saderta) Empty Slot Empty Slot PPC 750 (Synergy) PPC 750 (Synergy) Empty Slot Empty Slot PPC 750 (Synergy) 1394a I/F (Saderta) 1394a I/F (Saderta) Empty Slot PPC 750 (Synergy) Empty Slot Hard Drive Hard Drive Hard Drive Terminal Server SUN Ultra 10 Workstation SUN Ultra 10 Workstation Pentium III w/1394a analyzer (Saderta) Pentium III w/1394a analyzer (Saderta) Hard Drive Hard Drive SUN E3500 Workstation (35 GB HD) PPC 750 (Synergy) PPC 750 (Synergy) 1394a I/F (Saderta) Empty Slot Empty Slot Empty Slot Empty Slot 1394a I/F (Saderta) 1394a I/F (Saderta) Empty Slot Empty Slot Empty Slot Empty Slot PPC 750 (Synergy) PPC 750 (Synergy) 1394a I/F (Saderta) cPCI bus (6U chassis) cPCI bus (6U chassis) Built-In Power Supply Built-In Power Supply Legends Ethernet RS232 COTS IEEE 1394 I2C SCSI COTS Support Equipment JPL In-House Product Future Expansion 21

22. Example of Fault Injection in IEEE 1394 Bus Fault Injected in the Gap Count Register in the IEEE 1394 Bus Before Fault Injection After Fault Injection 22

23. Power PC 750 Processors IEEE 1394 BUS I2c bus Distributed Flight Computer Testbed 23

24. Guarded Software Upgrade • Motivation: • Flight software for long life deep space missions have to be upgraded periodically to correct design bugs or due to change of mission phases • Unprotected software upgrades have previously caused severe and costly damage to space missions and critical applications • Objectives: • Update flight software without System Reboot • Fall back to previous version of the software if failures occur during the upgrade • Approach: • Use the old version of the software to “guard” the new version during the transition • Turn over the control to the new software only when the right level of confidence is reached A. Tai, K. S. Tso, L. Alkalai, S. N. Chau, and W. H. Sanders, "On low-cost error containment and recovery methods for guarded software upgrading," in Proceedings of the 20th International Conference on Distributed Computing Systems (ICDCS 2000), Taipei, Taiwan, April 2000, pp. 548-555. A. T. Tai, K. S. Tso, L. Alkalai, S. Chau, and W. H. Sanders, "On the effectiveness of a message-driven confidence-driven protocol for guarded software upgrading,'' in Proceedings of the 4th IEEE International Computer Performance and Dependability Symposium (IPDS 2000), Schaumburg, IL, March 2000. 24

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43. Direction of Dependable Computing Researches for Future Flight Missions • Characteristics of Future Deep Space Missions: • Future Space Exploration Missions are ambitious: • Precision navigation control for spacecraft aerobraking and aerocapture • Precision entry-descent-landing with hazard avoidance • Highly autonomous operations • Long-duration missions in extreme environments • Miniaturized systems for sample returns, ascent vehicles, mobile units, etc. • Distributed surface science - network science - constellations of spacecraft • Formation flying (e.g., interferometry missions) • These missions require a new look at high performance dependable computing • Distributed processing among multiple spacecraft, and within a spacecraft • High performance computing and power efficient computing that supports long-life, high availability of systems • Autonomous, on-board fault-detection, isolation and repair • Fault adaptation • A framework for using COTS for the design of future, highly reliable systems 43

44. References • “COTS-Based Fault Tolerance in Deep Space: Qualitative and Quantitative Analyses of a Bus Network Architecture,” in Proceedings of the 4th IEEE International Symposium on High Assurance Systems Engineering, Washington D.C., Nov 1999 • “Design of a fault-tolerant COTS-based bus architecture, ” IEEE Trans. Reliability, vol. 48, pp. 351-359, Dec. 1999 • “The design of a fault-tolerant COTS-based bus architecture,” Pacific Rim International Symposium on Dependable Computing, Hong Kong, China, Dec. 1999 • "The Implementation of a COTS Based Fault Tolerant Avionics Bus Architecture", in the Proceedings of the Aerospace 2000 Conference, Big Sky, Montana, Mar. 2000 • "COTS-based fault tolerance in deep space: A case study on IEEE 1394 application," International Journal of Reliability, Quality and Safety Engineering, vol. 9, June 2002. • “A design-diversity based fault-tolerant COTS avionics bus network,” in Proceedings of the Pacific Rim International Symposium of Dependable Computing (PRDC 2001), Seoul, Korea, Dec. 2001. Note: Some of these references can be found in http://www.ia-tech.com/obm/ 44

45. References • "On the effectiveness of a message-driven confidence-driven protocol for guarded software upgrading," Performance Evaluation, vol. 44, pp. 211-236, Apr. 2001. • "Low-cost error containment and recovery for onboard guarded software upgrading and beyond," IEEE Trans. Computers, vol. 51, Feb. 2002. • “Low-cost flexible software fault tolerance for distributed computing,” in Proceedings of the 12th International Symposium on Software Reliability Engineering (ISSRE 2001), Hong Kong, China, pp.148-157, Nov. 2001. • "Synergistic coordination between software and hardware fault tolerance techniques," in Proceedings of the International Conference on Dependable Systems and Networks (DSN 2001), Goteborg, Sweden, July 2001. • "Onboard guarded software upgrading: Motivation and framework," in Proceedings of the IEEE Aerospace Conference, Big Sky, MT, Mar. 2001. • "On low-cost error containment and recovery methods for guarded software upgrading," in Proceedings of the 20th International Conference on Distributed Computing Systems (ICDCS 2000), Taipei, Taiwan, Apr. 2000. • "On the effectiveness of a message-driven confidence-driven protocol for guarded software upgrading,” in Proceedings of the 4th IEEE International Computer Performance and Dependability Symposium (IPDS 2000), Schaumburg, IL, Mar. 2000 45