Methods for Increasing the Radiation Resistance of 3D Integration Memory Modules for Aerospace Applications

Space radiation effects in electronics are significantly important during the development of devices for aerospace applications. Radiation tolerant component base significantly lag behind the commercial chips with regard to operating speed, memory capacity and etc. The issue of commercial memory use...

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Veröffentlicht in:International journal of innovative technology and exploring engineering 2019-10, Vol.8 (12), p.3551-3553
Hauptverfasser: Litvinenko, R.S., Prokofiev, I.V., Matveev, V.M.
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container_title International journal of innovative technology and exploring engineering
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creator Litvinenko, R.S.
Prokofiev, I.V.
Matveev, V.M.
description Space radiation effects in electronics are significantly important during the development of devices for aerospace applications. Radiation tolerant component base significantly lag behind the commercial chips with regard to operating speed, memory capacity and etc. The issue of commercial memory use in information storage devices is especially acute in conditions of high radiation. Within the framework on development of micromodule 3D integration technology for onboard equipment for aerospace applications, the study of the radiation effects influence on the operation of commercial NAND-Flash chips and methods of counteracting these effects are carried out.
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title Methods for Increasing the Radiation Resistance of 3D Integration Memory Modules for Aerospace Applications
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