TY - GEN
T1 - Nonvolatile logic-in-memory array processor in 90nm MTJ/MOS achieving 75% leakage reduction using cycle-based power gating
AU - Natsui, Masanori
AU - Suzuki, Daisuke
AU - Sakimura, Noboru
AU - Nebashi, Ryusuke
AU - Tsuji, Yukihide
AU - Morioka, Ayuka
AU - Sugibayashi, Tadahiko
AU - Miura, Sadahiko
AU - Honjo, Hiroaki
AU - Kinoshita, Keizo
AU - Ikeda, Shoji
AU - Endoh, Tetsuo
AU - Ohno, Hideo
AU - Hanyu, Takahiro
PY - 2013/4/29
Y1 - 2013/4/29
N2 - Nonvolatile logic-in-memory (NV-LIM) architecture [1], where magnetic tunnel junction (MTJ) devices [2] are distributed over a CMOS logic-circuit plane, has the potential of overcoming the serious power-consumption problem that has rapidly become a dominant constraint on the performance improvement of today's VLSI processors. Normally-off and instant-on capabilities with a small area penalty due to non-volatility and three-dimensional-stackability of MTJ devices in the above structure allow us to apply a power-gating technique in a fine temporal granularity, which can perfectly eliminate wasted power dissipation due to leakage current. The impact of embedding nonvolatile memory devices into a logic circuit was, however, demonstrated by using only small fabricated primitive logic-circuit elements [3], memory-like structures such as FPGA [4], or circuit simulation because of the lack of an established MTJ-oriented design flow reflecting the chip-fabrication environment, while larger-capacity and/or high-speed-access MRAM has been increasingly developed. In this paper, we present an MTJ/MOS-hybrid video coding hardware that uses a cycle-based power-gating technique for a practical-scale MTJ-based NV-LIM LSI, which is fully designed using the established semi-automated MTJ-oriented design flow.
AB - Nonvolatile logic-in-memory (NV-LIM) architecture [1], where magnetic tunnel junction (MTJ) devices [2] are distributed over a CMOS logic-circuit plane, has the potential of overcoming the serious power-consumption problem that has rapidly become a dominant constraint on the performance improvement of today's VLSI processors. Normally-off and instant-on capabilities with a small area penalty due to non-volatility and three-dimensional-stackability of MTJ devices in the above structure allow us to apply a power-gating technique in a fine temporal granularity, which can perfectly eliminate wasted power dissipation due to leakage current. The impact of embedding nonvolatile memory devices into a logic circuit was, however, demonstrated by using only small fabricated primitive logic-circuit elements [3], memory-like structures such as FPGA [4], or circuit simulation because of the lack of an established MTJ-oriented design flow reflecting the chip-fabrication environment, while larger-capacity and/or high-speed-access MRAM has been increasingly developed. In this paper, we present an MTJ/MOS-hybrid video coding hardware that uses a cycle-based power-gating technique for a practical-scale MTJ-based NV-LIM LSI, which is fully designed using the established semi-automated MTJ-oriented design flow.
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U2 - 10.1109/ISSCC.2013.6487696
DO - 10.1109/ISSCC.2013.6487696
M3 - Conference contribution
AN - SCOPUS:84876532836
SN - 9781467345132
T3 - Digest of Technical Papers - IEEE International Solid-State Circuits Conference
SP - 194
EP - 195
BT - 2013 IEEE International Solid-State Circuits Conference, ISSCC 2013 - Digest of Technical Papers
T2 - 2013 60th IEEE International Solid-State Circuits Conference, ISSCC 2013
Y2 - 17 February 2013 through 21 February 2013
ER -