TY - JOUR
T1 - A dynamic optically reconfigurable gate array - Perfect emulation
AU - Seto, Daisaku
AU - Watanabe, Minoru
N1 - Funding Information:
Manuscript received August 21, 2007; revised January 11, 2007 and November 14, 2007. This work was supported in part by the Ministry of Education, Science, Sports and Culture, Grant-in-Aid for Young Scientists (B), 18760256, 2007. The VLSI chip in this study was fabricated in the chip fabrication program of VLSI Design and Education Center (VDEC), the University of Tokyo, Japan, in collaboration with Rohm Company Ltd. and Toppan Printing Company Ltd.
PY - 2008
Y1 - 2008
N2 - This paper presents a perfect dynamic optically reconfigurable gate array (DORGA) architecture emulation using a holographic memory and a conventional ORGA-VLSI. In ORGAs, although a large virtual gate count can be realized by exploiting the large-capacity storage capability of a holographic memory, the actual gate count, which is the gate count of a programmable gate array VLSI, is important to increase the instantaneous performance. Nevertheless, in previously proposed ORGA-VLSIs, the static configuration memory to store a single configuration context consumed a large implementation area of the ORGA-VLSIs and prevented the realization of large-gate-count ORGA-VLSIs. Therefore, a DORGA architecture has been proposed in order to increase the gate density. It uses the junction capacitance of photodiodes as dynamic memory, thereby obviating the static configuration memory. However, to date, demonstration of a perfect optically reconfigurable architecture for DORGA-VLSIs has never been presented. Therefore, in this study, the DORGA architecture was perfectly emulated, and the performance, particularly the reconfiguration context retention time, was measured experimentally. The advantages of this architecture are discussed in relation to the results.
AB - This paper presents a perfect dynamic optically reconfigurable gate array (DORGA) architecture emulation using a holographic memory and a conventional ORGA-VLSI. In ORGAs, although a large virtual gate count can be realized by exploiting the large-capacity storage capability of a holographic memory, the actual gate count, which is the gate count of a programmable gate array VLSI, is important to increase the instantaneous performance. Nevertheless, in previously proposed ORGA-VLSIs, the static configuration memory to store a single configuration context consumed a large implementation area of the ORGA-VLSIs and prevented the realization of large-gate-count ORGA-VLSIs. Therefore, a DORGA architecture has been proposed in order to increase the gate density. It uses the junction capacitance of photodiodes as dynamic memory, thereby obviating the static configuration memory. However, to date, demonstration of a perfect optically reconfigurable architecture for DORGA-VLSIs has never been presented. Therefore, in this study, the DORGA architecture was perfectly emulated, and the performance, particularly the reconfiguration context retention time, was measured experimentally. The advantages of this architecture are discussed in relation to the results.
KW - Field-programmable gate arrays (FPGAs)
KW - Holographic memories
KW - Optical data processing
KW - Programmable logic devices
KW - Semiconductor laser arrays
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U2 - 10.1109/JQE.2008.916705
DO - 10.1109/JQE.2008.916705
M3 - Article
AN - SCOPUS:59549096337
SN - 0018-9197
VL - 44
SP - 493
EP - 500
JO - IEEE Journal of Quantum Electronics
JF - IEEE Journal of Quantum Electronics
IS - 5
ER -