Reconfigurable Computers in Space: Problems, Solutions and Future Directions

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Reconfigurable Computers in Space Problems,
Solutions and Future Directions

• Neil W. Bergmann, Anwar S. DawoodCRC for
  Satellite SystemsQueensland University of
  TechnologyGPO Box 2434, Brisbane 4001Australia
• Phone 61-7-3864-2785, Fax 61-7-3864-1516
  E-mail n.bergmann_at_qut.edu.au,
  a.dawood_at_qut.edu.auWWW http//www.crcss.qut.edu.
  au/

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Summary

• Interest in Reconfigurable Computing (RC) has
  recently spread to those interested in space
  missions.
• Although RC has sparked much interest in the
  general computing community, it has yet to
  demonstrate killer app status for any
  terrestrial applications.
• However, we believe that there are several
  compelling arguments about why RC is an excellent
  match to the requirements of space missions.
• This paper
• Describes these arguments,
• Looks at characteristics of the space
  environment,
• Looks at possible solutions to the use of RC in
  space, and
• Looks at possible long-term research directions.

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Why can space be a killer app for
Reconfigurable Computing?

• After launch, unmanned spacecraft electronics are
  generally unavailable for physical upgrade or
  repair. RC technology allows new hardware
  circuits to be uploaded via a radio link.
• New circuit configurations can overcome design
  faults, allow improved processing algorithms to
  be uploaded, or change system functionality in
  response to changing mission requirements.
• The same circuitry can be used with different
  configurations at different stages of a mission,
  reducing weight and power requirements.
• If part of an FPGA fails, then circuitry can be
  reprogrammed to make use of remaining functional
  portions of the chips.
• Use of FPGAs allows generic circuit boards to be
  designed, which are customised for individual
  applications. This helps overcome the very high
  NRE costs associated with small volume spacecraft
  design. Physical and environmental qualification
  costs can also be shared across many missions.
• In-flight reconfiguration provides additional
  safety margins for missions with very short
  lead-times, or for those where mission
  requirements are not fullt defined at launch.

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Problematic Aspects of Operating in Space

• Ionising radiation causes soft-errors in the
  static RAM cells used to hold programming
  information in FPGAs.Longer-term ionising
  radiation causes hard-errors in the electronic
  circuitry.
• Radio-links to spacecraft are often low bandwidth
  and high error-rate. This is not a good match to
  the relatively large configuration files of order
  1 Mbit required for modern FPGAs.
• Limited on-board memory restricts the number of
  different configurations that can be stored.
  Uploaded alternative configurations stored in
  EEPROM are also susceptible to radiation-induced
  errors.

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Short-term solutions for configuration errors

• FPGAs generally allow the configuration
  bit-stream to be read back to check for errors.
  The simplest FPGA-configuration error-detection
  technique simply examines the readback bitstream
  and compares it to the correct bitstream (or
  alternatively compares the CRC signature of the
  read-back stream to the desired). Correction is
  by reloading the FPGA configuration.
• Triple-redundancy voting circuits allow faulty
  FPGA circuits to be switched out and reprogrammed
  while the system is still operating.

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Short-term solutions for configuration management

• Techniques to assist with uploading new
  configurations aim to reduce configuration file
  sizes for storage and transmission.
• Techniques include specialised compression
  techniques, and differential configuration
  formats (relative to an on-board default
  configuration).
• CRC checks are necessary for on-board monitoring
  of configuration file integrity.
• For deep space missions, error correcting codes
  are desirable.

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Long-term solutions requiring special
space-friendly FPGAs

• Space-friendly FPGAs should provide on-chip
  configuration error-detection and/or correction
  circuitry which operates continuously and
  unobtrusively.
• Techniques will need to be developed to identify
  permanently faulty logic blocks within an FPGA,
  most likely by loading a special set of
  diagnostic configurations.
• Techniques are needed to allow existing circuit
  designs to be reconfigured on-board the
  spacecraft to avoid faulty logic cells. This is
  impractical with current generation
  place-and-route software.
• There is much scope for research into
  error-detecting or fault-secure logic circuit
  designs for FPGAs, based on a new single
  configuration bit-flip error model. These
  internally redundant logic gate designs could
  build strong fault tolerance into existing FPGA
  chips.
• A single chip or MCM combination of FPGA,
  microcontroller, flash memory configuration
  store, and digital and analog I/O circuitry would
  greatly reduce space mission weight and cost.

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Adaptive Instrument Module Payload

• This is being designed for the experimental
  FedSat LEO, due for launch in late 2001.
• This experiment provides a vehicle for validating
  our research ideas.
• A small (1kg) payload consisting of
• Microcontroller with RS422 communications
• SRAM-based FPGA (Xilinx X4062)
• RAM, PROM, Flash Memory storage
• Adaptive Instrument Port

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Conclusions

• Reconfigurable computing has many advantages for
  space applications, and is an excellent match to
  new directions in low-cost, flexible space
  missions.
• Existing FPGA architectures have significant
  operational issues (eg radiation induced errors)
  and management issues (such as configuration
  management).
• In the short term these issues can be identified
  and ameliorated by additional external circuit
  and system techniques
• In the long-term, these techniques need to be
  included as part of the FPGA chip design.
• Overall, there is potential for space-based
  computing to be a killer app for reconfigurable
  computing technology.