An MTJ-based logic-in-memory design performs fully parallel stochastic bit-stream generation and arithmetic without external random number generators by exploiting device stochasticity.
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DISCA achieves 3.59 TOPS/W per bit energy efficiency for matrix multiplication at 500 MHz in 180 nm CMOS using a compressed Bent-Pyramid stochastic format.
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Maximizing Memory-Level Parallelism via Integrated Stochastic Logic-in-Memory Architectures
An MTJ-based logic-in-memory design performs fully parallel stochastic bit-stream generation and arithmetic without external random number generators by exploiting device stochasticity.
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DISCA: A Digital In-memory Stochastic Computing Architecture Using A Compressed Bent-Pyramid Format
DISCA achieves 3.59 TOPS/W per bit energy efficiency for matrix multiplication at 500 MHz in 180 nm CMOS using a compressed Bent-Pyramid stochastic format.