Aika Kamei, Takuya Kojima, H. Amano, Daiki Yokoyama, Hisato Miyauchi, K. Usami, Keizo Hiraga, Kenta Suzuki, K. Bessho
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引用次数: 4
Abstract
In this study, a second-generation coarse-grained reconfigurable array with non-volatile flip-flops (NVFFs), known as the non-volatile cool mega array with multi-context (NVCMA/MC), is proposed. Similar to the previous NVCMA, verify-and-retriable NVFFs (VR-NVFFs) are provided for their configuration memory, constant memory, data memory, and instruction memory. The dedicated instructions for controlling the store, verify, and restore operations of the NVFFs are provided to the microcontroller in addition to power gating functions. Based on experience of the NVCMA, four hardware contexts are introduced to maintain the configuration data for four tasks, without the sacrifice of memory leakage. The array size is expanded, and pipeline registers are introduced to reduce the trade-off between the performance and power consumption. This study mainly focuses on the energy-saving effect of the VR-NVFFs and the multi-context facility of the NVCMA/MC, including the measurement of the break-even point. The evaluation of a real chip implemented with 40 nm MTJ/MOS hybrid process technology demonstrates that the store energy is reduced by 65% with the two-step store control of the VR-NVFFs. Moreover, applications that run intermittently for intervals as short as approximately 3 μs can benefit from the multi-context power gating.
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