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Reconfigurable Processing Building Blocks for Spacecraft MAPLD 2004 J. R. Marshall

Reconfigurable Processing Building Blocks for Spacecraft MAPLD 2004 J. R. Marshall. Agenda. Mission Needs for Reconfigurable Processing Elements Challenges to Realize Capabilities Reconfigurable Element Taxonomies Potential Reconfigurable Elements and Architectures

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Reconfigurable Processing Building Blocks for Spacecraft MAPLD 2004 J. R. Marshall

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  1. Reconfigurable Processing Building Blocks for SpacecraftMAPLD 2004J. R. Marshall

  2. Agenda • Mission Needs for Reconfigurable Processing Elements • Challenges to Realize Capabilities • Reconfigurable Element Taxonomies • Potential Reconfigurable Elements and Architectures • Lessons Learned and Summary 2

  3. Today’s Needs for Processing Building Blocks • Modular – Interchangeable Pieces, Mix and Match • Configurable – Plug and Play at Assembly • Reconfigurable – Change Mission after Launch • Responsive – Very Quick Turnaround • Power Efficient • Scalable: • ASICs to FPGAs to GPPs; • Single to Busses to Fabrics 3

  4. Missions • Micro-Satellites • Software Defined Radios • Reconfigurable Transceivers • Energy Measuring Systems • Communications Systems • Science Payloads • Combinations of Objectives and Applications • Very Long Timeframes • Quick Response Timeframes 4

  5. Value to Missions • Improve Performance without Hardware Upgrade • Rapid Response to New Requirements • Respond to Changing Environments or Multiple Missions • Shorter Development / Testing Cycles • Smaller Number of Unique Elements • Higher Reliability and Fault Tolerance • Significant Commercial Industry Focus • Leverages Many Complementary Technologies 5

  6. Ultimate Goals • Self Aware or Cognitive • Integrated Elements across all Materials • Lowest Power: Adaptable and Energy Conserving • Lasting State: Non Volatile and Radiation Hardened • Yet with Universal, Standard Interfaces • Result: a Reconfigurable Putty, that is anything but Silly! 6

  7. Radiation Challenges • Total Ionizing Dose • Technologies Improving as Size Decreases • Single Event Effects • Getting Worse – Must Continue to be Focus • Current Mitigation • Fuse-Based (modular and configurable – not reconfigurable) • TMR Circuits • Readback, Check and Reload of Configuration Memory • Mix and Match of Appropriate Elements vs. Application • Future Mitigation • NonVolatile Radiation Hardened Configuration Memory • HBD or Radiation Hardened Memory and Logic 7

  8. Clocking • Special Emphasis Needed Here across Reconfigurable Elements • Many standard interfaces have built in Clocks • PLLs Enable Lower Speed Clocks except when data must be tagged to the highest Frequency • Fastest Needs are for Point-to-Point Connection • Must be able to share data across multiple devices on same clock cycle 8

  9. Infrastructure • Can Not Be Ignored • Common Infrastructure Block • Pre Tested I/Os • Internal “Application” Design Easier • Enables Mixing and Matching of Cores • Cores • Both Logic and Memory Elements • Need internal Connection Medium for Devices • Pre-tested • Parameterized as Much as Possible – increases Flexibility • Support Tools and Environment • Leverage COTS Tools • Overlap Mission Users with Developers to Maximize Ease of Use and Testing 9

  10. Concentration of Interfaces and Power • Current FPGAs in Very High I/O (1000+ Pins) Packages • Maximum Capability Requires • Maximize Universal Interconnects • Maximize Thermal Paths • Maximize Thermal Cycling Capabilities • Maximize Modular Elements • Must be Space Qualifiable • Mechanical Challenges • High Density Reliable Pluggable Connectors • 3D Structures (daughter cards, etc.) Per Element on Backplane • Fabric Modularity on Backplanes (no SPOF) • Higher Density on Circuit Boards and Within Packages • Multiple Power Sources and Voltages • Thermal and Vibration Solutions • Reliability Challenges • Higher Fidelity Models 10

  11. Reconfigurable Element Taxonomies MEMS ATOMIC STRUCTURES MATERIALS PROGRAMMABLE FIXED STATES INTERCONNECT FABRIC WIRES CHANGEABLE, KNOWN STATES ANALOG POWER EVOLVABLE, REACTIVE, AUTONOMOUS DIGITAL MWAVE DSP FPGA ASIC FILTERS GPP S-A GA SELF- AWARE, COGNITIVE XCVRS PHYSICAL BREADTH OF CHANGE USER INTERFACE TRAINING TRAINING DESIGN ENVIRON- MENT TEST EQUIPMENT T&C INTERFACE INFRASTRUCTURE SUPPORT SOFTWARE ELEMENT LIBRARY MISSION TESTING DEVELOPMENT MISSION 11

  12. Interface Hierarchy BOX CHIP CARD or BOARD On Board or MCM Backplane Busses CHIP CARD or BOARD Fabrics External Interfaces PERIPHERAL MCM or Hybrid CHIP CHIP CHIP BACKPLANE PERIPHERAL FABRIC CARD or BOARD CHIP CARD or BOARD CHIP CHIP CHIP SW CHIP CHIP CARD or BOARD CARD or BOARD SW SW CHIP CHIP CARD or BOARD CARD or BOARD PERIPHERAL PERIPHERAL CARD or BOARD B O X B O X B O X FABRIC CHIP CHIP CHIP 12

  13. Near Term Recommended Electrical Interfaces • On Board or MCM (chip to chip) • LVTTL/LVCMOS • LVDS • ISA • PC/104 • PCI / PCI-X (3.3V Signaling) • PCI Express • RocketIO or similar transceiver • Rapid I/O • HyperTransport • Backplane Busses or Interconnects • All LVTTL/LVCMOS • LVDS • RocketIO or similar transceiver • ISA • CompactPCI (3.3V Signaling) • PCI-X (3.3V Signaling) • PCI Express • VME • MIL-STD-1553B • Fabrics • SpaceWire using LVDS, RocketIO or similar • RapidIO • Serial RapidIO • Ethernet • InfiniBand • Star Fabric • Advanced Switching • External Interfaces • LVDS • RocketIO or similar transceivers • 3.3V LVTTL/LVCMOS • RS-422 • PECL • I2O • SpaceWire using LVDS, RocketIO or similar • Serial RapidIO • IEEE 1394 • MIL-STD-1553B • USB Green = External PHY; Blue = Recommended 13

  14. Current Reconfigurable Elements 6U • Features • 50/100 MHz Operation • 1-3 x 1M gate RAM-Based FPGAs • Up to 192 MB FPGA-Shared SDRAM • 1-4 MB FPGA Configuration Memory • Auto Configuration & Readback • Common Infrastructure Block provides Pre-tested Board I/O • 33 MHz Microcontroller with 256 KB EEPROM and 64 KB Scratchpad RAM • 33 MHz CompactPCI I/F • 1-3x32 Bit 50 MHz Data Ports • 50+ External FPGA I/Os • Thermistor on each FPGA • SEM-E Stretch or cPCI 3U/6U Card • 2 W (Standby) up to 30 W (Max) • Application Switch in < 1 sec • 3 us frame / 20 ms FPGA reload • Development/Test Environment 3U SEM-E Stretch 14

  15. Reconfigurable Interfaces Architecture 15

  16. Lessons Learned • Must have more standard interfaces • Infrastructure will enable true reconfiguration – don’t forget mission user and operator training • Seldom does one processing technology fit all needs – i.e., mix from GPPs to FPGAs to ASICs • Must Always Lower Power, period. • Power, Thermal and Mechanical are true enablers for future progress 16

  17. Summary • Modular, Configurable, Reconfigurable, Responsive and Scalable driving need for Reconfigurable Processing Elements - spans physical, behavior and infrastructure • Starting to see some products in Space – expect explosion utilizing new technologies in coming years with significant gains in performance and behavior • Must find ways to standardize as in CPUs and maximize interconnects yet lower power and be adaptive to environment • Someday will have reconfigurable Putty (that is not Silly!) 17

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