TY - GEN
T1 - Investigating the radiation tolerance of a laser array for an optically reconfigurable gate array
AU - Akagi, Kouta
AU - Watanabe, Minoru
N1 - Publisher Copyright:
© 2015 The Japan Society of Applied Physics.
PY - 2016/2/23
Y1 - 2016/2/23
N2 - Optically reconfigurable gate arrays (ORGAs) have been developed to realize radiation-hardened field programmable gate arrays (FPGAs). An ORGA consists of a laser array, a holographic memory, and a programmable gate array VLSI. Since the configuration of an ORGA is a parallel configuration, damage to a configuration circuit or a component does not affect configuration procedures on other configuration circuits. Therefore, even if almost all look-up tables (LUTs) malfunction because of radiation, the remaining functional LUTs can be programmed and used, whereas the serial configuration of FPGAs does not allow the use of a partly failed gate array. However, to achieve higher radiation tolerance of a programmable gate array than that of an FPGA in ORGA architecture, the radiation tolerances of a laser array and a holographic memory must be sufficiently higher than that of the part of a programmable gate array VLSI. Since the radiation tolerance of a holographic memory has already been confirmed as sufficiently higher than that of a programmable gate array VLSI, this paper presents a radiation tolerance investigation of a laser array on an optically reconfigurable gate array. Experiments using Co60 gamma radiation have demonstrated that a laser array has a greater than 20 Mrad total ionizing dose tolerance.
AB - Optically reconfigurable gate arrays (ORGAs) have been developed to realize radiation-hardened field programmable gate arrays (FPGAs). An ORGA consists of a laser array, a holographic memory, and a programmable gate array VLSI. Since the configuration of an ORGA is a parallel configuration, damage to a configuration circuit or a component does not affect configuration procedures on other configuration circuits. Therefore, even if almost all look-up tables (LUTs) malfunction because of radiation, the remaining functional LUTs can be programmed and used, whereas the serial configuration of FPGAs does not allow the use of a partly failed gate array. However, to achieve higher radiation tolerance of a programmable gate array than that of an FPGA in ORGA architecture, the radiation tolerances of a laser array and a holographic memory must be sufficiently higher than that of the part of a programmable gate array VLSI. Since the radiation tolerance of a holographic memory has already been confirmed as sufficiently higher than that of a programmable gate array VLSI, this paper presents a radiation tolerance investigation of a laser array on an optically reconfigurable gate array. Experiments using Co60 gamma radiation have demonstrated that a laser array has a greater than 20 Mrad total ionizing dose tolerance.
KW - Field programmable gate arrays
KW - Holographic optical components
KW - Holography
KW - Logic gates
KW - Optical arrays
KW - Very large scale integration
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U2 - 10.1109/MOC.2015.7416484
DO - 10.1109/MOC.2015.7416484
M3 - Conference contribution
AN - SCOPUS:84969529091
T3 - MOC 2015 - Technical Digest of 20th Microoptics Conference
BT - MOC 2015 - Technical Digest of 20th Microoptics Conference
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 20th Microoptics Conference, MOC 2015
Y2 - 25 October 2015 through 28 October 2015
ER -