Title :
Total-dose issues for microelectronics in space systems
Author :
Pease, Ronald L.
Author_Institution :
RLP Res., Albuquerque, NM, USA
fDate :
4/1/1996 12:00:00 AM
Abstract :
Ionizing radiation has been a problem for space-system microelectronics from the earliest satellites. Much progress has been made in understanding the physical mechanisms that cause total-dose-induced failure, and this knowledge has been applied to hardened-technology development. Many of the hardened technologies are no longer available, however, and hence more commercial off-the-shelf components are being used. This situation presents a challenge for system designers, since the commercial parts typically have lower failure levels and larger variability in response. In addition, recent studies have uncovered new challenges for total-dose hardness assurance in the form of 1) an enhanced low dose-rate sensitivity of bipolar linear microcircuits, 2) an effect of burn in on CMOS microcircuit total-dose response, and 3) an enhanced effect of plastic packaging on the burned-in effect for CMOS circuits. These issues are addressed as they relate to the space-system ionizing radiation environment
Keywords :
CMOS integrated circuits; aerospace instrumentation; artificial satellites; bipolar analogue integrated circuits; integrated circuit packaging; integrated circuit testing; radiation hardening (electronics); space vehicle electronics; CMOS microcircuit; bipolar linear microcircuits; burn in; burned-in effect; ionizing radiation; ionizing radiation environment; low dose-rate sensitivity; microelectronics; off-the-shelf components; plastic packaging; space systems; total-dose hardness assurance; Artificial satellites; Books; Circuits; Ionizing radiation; Microelectronics; Passivation; Plastic packaging; Radiation hardening; Silicon; Space technology;
Journal_Title :
Nuclear Science, IEEE Transactions on
