TY - GEN
T1 - 300 Mrad total-ionizing-dose tolerance of a holographic memory on an optically reconfigurable gate array
AU - Ito, Yoshizumi
AU - Watanabe, Minoru
AU - Ogiwara, Akifumi
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2017/7/5
Y1 - 2017/7/5
N2 - Currently, radiation-hardened field programmable gate arrays (FPGAs) are sought for embedded systems designed for use in space. However, in terms of soft-error and permanent failure, the radiation tolerances of configuration memories on current FPGAS are not high. Therefore, to remove the soft-error on configuration memories of FPGAS, optically reconfigurable gate arrays with a parallel configuration capability have been proposed. The optically reconfigurable gate array consists of an optically reconfigurable gate array VLSI, a holographic memory, and a laser array. Since the optically reconfigurable gate array allows high-speed scrubbing of its configuration memory, the soft-error factor on configuration memory can be removed from consideration. Moreover, the parallel configuration allows uses of radiation-damaged gate arrays so that the optically reconfig-urable gate array can increase the radiation tolerance. However to support such high-speed scrubbing, its optical part must work correctly even if it receives a large amount of radiation. This paper therefore presents a system in which the holographic memory can function correctly despite exposure up to 300 Mrad total-ionizing-dose, which is 300-times-higher radiation tolerance than those of current VLSIs and FPGAS.
AB - Currently, radiation-hardened field programmable gate arrays (FPGAs) are sought for embedded systems designed for use in space. However, in terms of soft-error and permanent failure, the radiation tolerances of configuration memories on current FPGAS are not high. Therefore, to remove the soft-error on configuration memories of FPGAS, optically reconfigurable gate arrays with a parallel configuration capability have been proposed. The optically reconfigurable gate array consists of an optically reconfigurable gate array VLSI, a holographic memory, and a laser array. Since the optically reconfigurable gate array allows high-speed scrubbing of its configuration memory, the soft-error factor on configuration memory can be removed from consideration. Moreover, the parallel configuration allows uses of radiation-damaged gate arrays so that the optically reconfig-urable gate array can increase the radiation tolerance. However to support such high-speed scrubbing, its optical part must work correctly even if it receives a large amount of radiation. This paper therefore presents a system in which the holographic memory can function correctly despite exposure up to 300 Mrad total-ionizing-dose, which is 300-times-higher radiation tolerance than those of current VLSIs and FPGAS.
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U2 - 10.1109/ISNE.2017.7968743
DO - 10.1109/ISNE.2017.7968743
M3 - Conference contribution
AN - SCOPUS:85027103647
T3 - 2017 6th International Symposium on Next Generation Electronics, ISNE 2017
BT - 2017 6th International Symposium on Next Generation Electronics, ISNE 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 6th International Symposium on Next Generation Electronics, ISNE 2017
Y2 - 23 May 2017 through 25 May 2017
ER -